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Lecture N0te5 1n Earth 5c1ence5 Ed1t0r5: 5.8hattacharj1, 8r00k1yn 6. M. Fr1edman, 8r00k1yn and 7r0y H. J. Neu9e6auer, 80nn A. 5e11acher, 7ue61n9en and Ya1e
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Preface
In this volume, we hope to bring together a general introduction to the study of impact structures and ejecta deposits, and a detailed description of how and where to find such impact deposits (for example, in the form of so-called impactoclastic layers) in the field. The marine sedimentary rocks of the Umbria-Marche (U-M) basin in Italy provide a remarkably complete and continuous stratigraphic record from the Late Triassic to the Pleistocene. Several major impact events happened during this time period, and the signatures of these impact events can be recognized in the field in the U-M sequence. It was in this region of Italy, near the town of Gubbio, where, in 1979, a team of researchers from Berkeley discovered extraterrestrial signal in the Cretaceous-Tertiary (K/T) boundary layer. It was this discovery that led to the hypothesis that the major extinction event, which occurred at the end of the Cretaceous, was caused by the impact of an asteroid or comet on Earth. The resulting vigorous scientific debate gave great publicity (not only among geoscientists) to impact research, which had been pursued for several decades by planetary geologists, cosmochemists, and mineralogists/petrologists who were interested in shock metamorphism. The wider geological community had not been aware of their work, which led to misunderstandings and heated debates that could have been avoided if the data and evidence on impact research would have been more widely known. The last two decades have seen great progress. The findings of shocked minerals at the K/T boundary and the identification of the (buried) Chicxulub impact structure in Mexico as the K/T source crater led to a wide acceptance of the reality of an impact event at the K/T boundary among researchers. Nevertheless, no textbook is currently available that reviews impact processes and their deposits, and how to find them in the field. We hope that the present book will help to fill this gap. The impetus for writing the present volume came from two different sources. First, an enormous amount of studies has been done over many decades on the UM sequence (including work by one of us [A.M.], impact-related or not), and nowhere was this work summarized or discussed, especially with respect to the well-preserved impact signatures in this record. Second, in 1998, the European Science Foundation (ESF) launched a new scientific program on "Response of the Earth System to Impact Processes" (IMPACT), with one of us (C.K.) being the chairman of this program, and one of the first activities within the IMPACT program was the organization of a (probably annual) short course on "Impact Stratigraphy" in Coldigioco, to study the impact record of the U-M sequence. The idea of this book grew out of the need to produce course notes for this class, which
VIII
was held for the first time in May 1999. The present volume is the result of a yearlong gestation period following the preparation of this course. The book is organized in two major parts and several chapters. Chaps. 1-3 set the stage on impact cratering and provide background information on the study of shock metamorphism, impact ejecta, and descriptions of distal ejecta from around the world. Chap. 4 introduces the geology of the Umbria-Marque sequence, and Chap. 5 gives detailed descriptions of the rock units in the U-M sequence, especially of those that have been found to contain impactoclastic layers. Chap. 6 discusses a few pertinent sampling and analysis techniques. Detailed location and outcrop maps and photographs should allow the reader or student to locate the discussed layers in the field. Almost all locations are easily accessible. Thus, the book will hopefully serve as both, an introduction into impact stratigraphy, and a field guidebook.
CotdigiocoNienna, January 2000
Christian Koeberl University of Vienna Vienna Austria
Alessandro Montanari Osservatorio Geologico di Coldigioco Frontale di Apiro Italy
Acknowledgements The authors wish to thank a long list of colleagues, friends, and family, for help, comments, data, images, support, and patience. The following are especially acknowledged for providing figures: B.F. Bohor (U.S. Geological Survey, Denver, USA), P. Claeys (Museum of Natural History, Berlin, Germany), V.L. Masaitis (Karpinsky Institute, St. Petersburg, Russia), L. Pesonen (Geological Survey of Finland), C.W. Poag (U.S. Geological Survey, Woods Hole, USA), W.U. Reimold (Wits University, Johannesburg, South Africa), V.L. Sharpton (University of Alaska, Fairbanks), J. Smit (Free University, Amsterdam, The Netherlands). Other figures without acknowledgements are by the authors. Dona Jalufka (Vienna) is much appreciated for drafting many of the line drawings in Chaps. 1-3 and 6. In addition, several colleagues read the various chapters of this book and prevented us from publishing too many errors and misconceptions (which does not mean that none remain): W.U. Reimold (Chap. 1), B.P. Glass (Chaps. 2, 4, 5, and 6), I. Gilmour (Chap. 3), and J. Smit (Chaps. 4 and 5). We appreciate financial assistance from the ESF IMPACT program, from the Austrian Fonds zur F6rderung der wissenschaftlichen Forschung (Y58-GEO), and from the Austrian-Italian Scientific and Technical Exchange Program ((3AD) for work related to, and for the preparation of, this volume. It almost goes without saying how grateful we are to our wives (Paula Metallo and Dona Jalufka, respectively) for their patience with us during the long months of work on this book. Furthermore, we acknowledge the students, who participated in the first "Impact Stratigraphy" short course (A. Abels, Mfinster; D. Boamah, Vienna; I. Dalwigk, Stockholm; S. Heuschkel, Berlin; H. Huber, Vienna; B. Kettrup, Mtinster; D. Kettrup, Mtinster; J.-M. Lange, Dresden; J. Monteiro, Lisbon; A. Rimsa, Vilnius; T. Salge, Berlin; E.G. Serrano, Madrid; S. Suuroja, Tallinn), who helped to test the curriculum. We are also grateful to W. Engel, A. Weber-Knapp, J. Sterrit-Brunner, and A. Bernauer-Budimann, all at Springer Verlag, for their help with, and support of, this project, and, last but not least, to J. Dryden (Open University, U.K.) for her excellent typesetting work of the manuscript.
Table of Contents
Introduction: Impact Cratering as a Geological Process .................. 1 1.1 1.2 1.3 1.4 1.5 1.6
1.7 1.8
1.9
Historical Background ............................................................................. 1 General Characteristics of Impact Craters ............................................... 7 Recognition of Impact Structures .......................................................... 10 Formation of Impact Craters ................................................................. 14 Shock Waves and the Stages of Crater Formation ................................ 16 Shock Metamorphic Effects .................................................................. 21 1.6.1 General .................................................................................... 21 1.6.2 Shatter Cones ........................................................................... 25 1.6.3 Mosaicism ............................................................................... 27 1.6.4 Planar Microstructures ............................................................ 27 1.6.5 Bulk Optical and other Properties ........................................... 33 1.6.6 Diaplectic Glass ...................................................................... 34 1.6.7 High-Pressure Polymorphs ...................................................... 34 1.6.8 Mineral and Rock Melts .......................................................... 36 Classification of Impactites .................................................................... 39 Meteoritic Components in Impactites .................................................... 42 1.8.1 Meteoritic Components and Siderophile Element Analyses .... 43 1.8.2 Problems with Meteoritic Component Identification ............... 47 1.8.3 Osmium Isotopes in Impact Studies ......................................... 49 1.8.4 Chromium Isotope Systematics ................................................ 50 Dating of Impact Structures .................................................................... 51
2 Distal Ejecta and Tektites 2.1 2.2 2.3 2.4 2.4.1
..........................................................................
Characteristics of Proximal and Distal Ejecta ........................................ Distal Ejecta as Stratigraphic Markers ................................................... Importance of the K/T boundary ............................................................ Tektites and Microtektites ...................................................................... Geographical Distribution: Strewn Fields and Age ................................ 2.4.2 Definition and Classification of Tektites ................................. 2.4.3 Petrology and Geochemistry of Tektites .................................. 2.4.4 Source Rocks of Tektites .......................................................... 2.4.5 Source Craters of Tektites ........................................................
57
57 60 63 64 68 69 71 79 80
XII
2.5
2.4.5.1 North American Strewn Field .................................... 2.4.5.2 Central European Strewn Field .................................. 2.4.5.3 Ivory Coast Strewn Field ........................................... 2.4.5.4 Australasian Strewn Field .......................................... 2.4.6 Tektite Formation: Facts and Open Questions ......................... Other Impact Glasses: Relation to Source Craters ................................. 2.5.1 Libyan Desert Glass .................................................................
3 Important Distal Ejecta Layers and Their Source Craters
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3.1 3.2
3.3
3.4 3.5 3.6 3.7
3.8
General The K/T Boundary and Chicxulub ....................................................... 3.2.1 Evidence for Impact at the K/T boundary .............................. 3.2.1.1 PGE Enrichments ..................................................... 3.2.1.2. PGE Abundance Patterns; K/T boundary Meteorite? ................................................................ 3.2.1.3 Meteoritic Os- and Cr-isotopic signature ................. 3.2.1.4 Soot and Organic Chemistry .................................... 3.2.1.5 Evidence of shock metamorphism ........................... 3.2.1.6 Impact glass .............................................................. 3.2.1.7 Impact-derived diamonds ......................................... 3.2.1.8 Occurrence of spinel ................................................ 3.2.2 Chicxulub Impact Structure: Relation to the K/T Event ........ 3.2.3 Chicxulub and the K/T Mass Extinction ................................ Late Eocene Impact Layers .................................................................. 3.3.1 Chesapeake Bay ..................................................................... 3.3.2 Popigai .................................................................................... Manson Impact Structure and Ejecta Layer ......................................... Acraman Impact Structure and Ejecta Layer ........................................ Morokweng and the Jurassic-Cretaceous Boundary ............................ Other Confirmed and Possible Ejecta Layers ....................................... 3.7.1 South African and Australian Archean Spherule Layers ....... 3.7.2 Late Devonian Impact Layer and Alamo Breccia .................. 3.7.3 Permian-Triassic Boundary ................................................... 3.7.4 Triassic-Jurassic Boundary .................................................... Outlook ................................................................................................. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4 The Umbria-Marche Sequence . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 4.2
Tectonic Setting .................................................................................... Stratigraphic Framework of the U - M Carbonate Sequence ................. 4.2.1 Triassic-Lower Cretaceous .................................................... 4.2.2 Upper Cretaceous-Oligocene ................................................. 4.2.3 Miocene ..................................................................................
80 85 86 88 89 93 95
]0l 101 101 104 104 105 106 107 109 111 112 113 114 123 130 132 133 136 138 139 142 142 148 150 151 152
157
157 162 162 163 166
XIII
5 Impact Stratigraphy in the U-M Sequence .......................................... 5.1 5.2 5.3 5.4 5.5 5.6 5.7
5.8
Searching for Impact Signatures in the Stratigraphic Record .............. 167 The TR/J Record ................................................................................... 172 The Pliensbachian-Toarcian boundary at Valdorbia ........................... 173 The J/K Record ..................................................................................... 177 The Upper Aptian Event ....................................................................... 181 The Cenomanian-TuronianBoundary ................................................. 184 The Terminal Cretaceous Record ......................................................... 190 5.7.1 The Maastrichtian ................................................................... 192 5.7.2 Definition of the K/T Boundary in the U - M Basin ............... 197 5.7.3 Sedimentary Setting and K/T Boundary "facies". ................. 201 5.7.4 Impact and Catastrophe Signatures in the U - M K/T Clay ..... 203 5.7.5 High-resolution Impact Stratigraphy of the K/T Event .......... 215 5.7.6 Representative K/T Boundary Outcrops in the U - M Basin... 222 The Paleogene Impact Record .............................................................. 250 5.8.1 The Paleocene-Eocene Boundary .......................................... 250 5.8.2 The Terminal Eocene Events ................................................. 254 The Global Stratotype Section and Point for the E/O 5.8.3 Boundary at Massignano ....................................................... 258 5.8.4 Impact Signatures at Massignano ........................................... 262 5.8.5 High-resolution Impact stratigraphy at Massignano .............. 268 The U - M Miocene Record ..................................................... 274 5.9
6 Documentation and Laboratory Techniques ..................................... 6.1 6.2
6.3
Documentation and Sampling in the Field ........................................... Sample Preparation 6.2.1 B u l k Samples .......................................................................... 6.2.2 Isolation o f Grains and Inclusions .......................................... Laboratory Techniques ......................................................................... 6.3.1 Standard Bulk and Microprobe Analysis Methods ................ 6.3.2 Iridium Determinations .......................................................... 6.3.3 Platinum Group Element Determinations .............................. 6.3.4 Osmium Isotope Measurements ............................................. 6.3.5 Methods for Shocked Quartz Measurements ......................... . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
References Index
167
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
279 279 282 282 283 286 286 289 291 292 295
301 353
1 Introduction: Impact Cratering as a Geological Process
Over the last 15 years, impact cratering as a geological process has received a much wider acceptance than before, largely due to research associated with the mass extinction at the end of the Cretaceous, and as a result of extensive planetary studies. Geological, geophysical, petrographical, and geochemical studies during mainly the last 30 years have led to the recognition of about 160 impact structures on Earth. Distal ejecta, which are one of the main focal points of this book, were distributed by some of the impact events associated with the formation of these structures. In some cases, distal ejecta were found without an obvious link to a sottrce crater, and their study led to the discovery of previously unknown impact structures. The most prominent case was the discovery that impact debris is associated with the Cretaceous-Tertiary (K/T) boundary layer. To allow identification of impact ejecta and impact structures it is necessary to understand fundamental mineralogical and geochemical properties of impactderived rocks. Very high pressures and temperature affect the target rocks during an impact event. These P-T conditions are significantly different, and higher, than those reached during any internal terrestrial process. The most characteristic changes induced by the impact-generated shock waves include irreversible changes in the crystal structure of rock-forming minerals, such as quartz and feldspar, and the formation of high-pressure modifications of minerals. These shock metamorphic effects are characteristic of impact and do not occur in natural materials formed by any other process. Furthermore, geochemical studies allow the detection of minute traces of the meteoritic projectile in impact melt rocks and glasses. In this first section we will briefly review the characteristics of impact structures (following earlier summaries by, e.g., Koeberl 1996, 1997a, 1998; French 1998), their formation, and the mineralogical, petrographical, and geochemical evidence for an impact origin of crater rocks or ejecta.
1.1 Historical Background Craters are a fundamental and common topographic form on the surfaces of planets, satellites, and asteroids. On large planetary bodies, of the size of the Moon and larger, craters can form in a variety of processes, including volcanism, impact, subsidence, secondary impact, and collapse. The two most important
Fig. 1.I.1. Asteroid Gaspra, photographed by the Galileo spacecraft, showing numerous impact craters on its surface.
processes are volcanism and impact. On smaller bodies (e.g., of the size of minor planets), impact may be the only process that can form craters (as shown, for example, by the numerous craters that pockmark the surfaces of asteroids; Fig. 1.1.1). In the explanation of terrestrial crater-like structures, the interpretation as volcanic features and related structures (such as calderas, maars, cinder cones) has traditionally dominated over impact-related interpretations. During the 1980s and early 1990s, a lively debate was held in the geological community regarding the cause of the mass extinction that marks the end of the Cretaceous Period. Interest in the events at the K/T boundary was renewed by the publication of the paper by Alvarez et al. (1980), who found that the concentrations of some rare siderophile elements are up to 4 orders of magnitude higher in the thin clay layer marking the K/T boundary than normally found in terrestrial crustal rocks. These observations were interpreted by Alvarez et al. (1980) as the result of a large asteroid or comet impact, which caused extreme environmental stress, leading to the mass extinction. At least the first part of this hypothesis was later strongly supported by the finding of shocked minerals in the K/T boundary layer by Bohor et al. (1984, 1987a) (see Sect. 3.2.1). In the absence of detailed knowledge of impact cratering and shock metamorphic processes in the general geological community, many researchers still favored a volcanic explanation for the "K/T event". Similar debates - regarding impact versus internal origin - have been held in discussing the origin of a variety of "unusual" structures around the world. The history of the study of impact craters begins with Galileo Galilei (15641642), when he first pointed a telescope at the Moon in the year 1609. He noticed circular spots and recognized, after studying the moving shadows over a few days time, that these features are depressions on the surface of the Moon. He also noticed that some of these craters have central peaks. The first drawings of lunar craters were published by Galileo in 1610 in his book "Sidereus Nuncius" ("The Starry Messenger"), but the low quality of his early telescope and the distortion of his drawings make it very difficult to identify the craters. Galileo himself did not seem to have any specific opinion regarding the origin of these structures, but most later astronomers preferred the volcanic hypothesis for the formation of the lunar craters. Soon after Galileo's work, much better lunar maps were published. The first map on which lunar formations were named was published by Michel Florent van Langren in 1645. Shortly thereafter (1647), the German astronomer Johannes Hevelius published his famous "Selenographia". The first speculations about the origin of lunar craters seem to date back to the British physicist Robert Hooke (1635-1703), who compared lunar craters to pits that remained on the surface of boiled alabaster. He also considered an impact theory and made a few crude experiments by dropping objects into mud. However, because the interplanetary space was at that time considered to be empty, he did not follow 'up on this hypothesis and rather thought that lunar craters may have formed from some kind of internal volcanic activity. The next few hundred years were dominated by the volcanic theory. The astronomer Friedrich Wilhem Herschel (1738-1822) (the discoverer of Uranus) allegedly saw in 1787 a volcanic
eruption on the Moon. Most experts had accepted the volcanic hypothesis, although a few voices remained in favor of an impact origin, such as, in 1829, the German astronomer Franz von Paula Gruithuisen. However, it did not help the impact hypothesis that Gruithuisen had announced a few years earlier that he had seen inhabited cities on the Moon, complete with cows grazing on lunar meadows. During these times, the study of lunar craters was an affair mainly for astronomers (for a review, see Schultz 1998). The few geologists that were concerned about lunar craters supported the volcanic hypothesis. The first serious study of the impact hypothesis of lunar craters dates back to Grove Karl Gilbert (18431918), whose positions included Chief Geologist of the U.S. Geological Survey and President of the Philosophical Society of Washington. In 1892, after detailed studies of lunar craters and after performing impact experiments in his hotel room during a lecture tour, he concluded that only the impact hypothesis was able to explain the formation of the lunar craters. However, he also recognized that the circularity of basically all lunar craters present one of the major problems of the impact hypothesis (as formulated at that time): due to the variation in impact angle relative to the surface (from vertical, or 90 °, to near 0 °) the resulting craters should mostly be elliptical in shape and not circular. Only decades later was the solution to this problem found. Another scientist, who was ahead of his times in other topics as well, studied lunar craters shortly after Gilbert and concluded that the craters on the Moon were of meteorite impact origin: Alfred Wegener (1880-1930), famous for his work on continental drift, published a little-known booklet (Wegener 1921), in which he discussed his impact experiments and conclusions regarding lunar and some terrestrial craters (cf. Greene 1998). Similar to his ideas on continental drift (which were only accepted many decades later), his views on lunar craters were largely ignored. Not only during the 19th, but also during most of the 20th century, the concept of impact cratering on Earth has not been much accentuated in classical geological studies. The ideas of "modem" geology, as expressed by, for example, James Hutton (1726-1797) and Charles Lyell (1797-1875), proposed that slow, endogenic processes lead to gradual changes in our geological record. In this uniformitarian view, internal forces are preferred over seemingly more exotic processes to explain geological phenomena that often give the impression of occurring over very long periods of time. In contrast, impact appears as an exogenic, relatively rare, violent, and unpredictable event, which violates every tenet of uniformitarianism (cf. Marvin, 1990). This may explain why many geologists over much of this century have opposed the explanation of craters on the Moon or on Earth as being of impact origin. Taken at face value, the Lyellian view of geology excludes any catastrophic event that is not directly observed. In contrast, the geological history of our planet is marked by rare catastrophes that only occur a few times in a million years (e.g., huge volcanic eruptions, gigantic floods). The history of study and acceptance of impact cratering over this century is somewhat similar to the record of the acceptance of plate tectonics (see, e.g., Mark 1987; Hoyt 1987; Marvin 1990; Glen 1994; D'Hondt 1998; for historical accounts
of impact crater studies). One of the reasons that continental drift (later called plate tectonics) found little acceptance early on was the absence of any known mechanism for moving continents. Only later, after irrefutable geophysical evidence had been found that the continents have indeed moved, were geologists forced to find a mechanism to explain these observations. Impact cratering had a similar fate: no mechanism was known to produce large circular craters by impact. Here, the situation is even more complicated, because even after some craters on Earth had clearly been shown to be the result of impact events, and after a physically plausible mechanism for their formation had been found, the process of impact cratering was still not widely accepted among geologists. Part of the reason was that impact mechanics were explained by astronomers and physicists whose goal it was to explain the formation of lunar craters. In contrast, the existence of internal mechanisms on Earth that result in craters of various forms and sizes made it unnecessary for geologists to resort to extraterrestrial explanations. One of the first studies that demonstrated that, due to very high velocities with which a body hits the Moon or the Earth, impacts are similar to explosions, and, therefore, resulting craters are always circular, was formulated by the Estonian astronomer Ernest Opik in 1916. Unfortunately he published his findings in Russian, with a French abstract, in a little-known Estonian journal, which made sure that almost nobody (certainly no geologists) paid any attention (Opik 1916). Later work by the New Zealand astronomer Algernon Charles Gifford, which was published in 1924 and 1930 in English in a more widely read journal (Gifford 1924), finally caused at least astronomers and physicists to take notice. These developments happened around the time that the mining engineer Daniel Morean Barringer (1860-1929) was actively involved in studying the "Coon Butte" or "Crater Mountain" structure in central Arizona. Iron meteorite fragments had been found around this 1.2 km diameter crater. Despite the opinion of several leading geologists (including Gilbert) that this structure was of volcanic origin and the presence of the meteorite fragments was only a coincidence, Baxringer was convinced that this was an impact crater. His subsequent exploration of the crater, from about 1903 until his death in 1929, was mainly driven by the desire to find large metallic (meteoritic) deposits underneath the crater floor, which could be exploited for rare metals. No such large iron meteorite mass was ever found leading many geologists to be more convinced than ever that impact had nothing to do with the formation of this structure. Nevertheless, physicists and astronomers, by now familiar with Opik's and Gifford's arguments, had no problem in explaining both the impact origin of the structure (now called "Meteor Crater") and the absence of large amounts of meteoritic material: only a body of 30 to 50 m in diameter is required to cause a crater with a diameter of more than lkm. The early work by Barringer and others on Meteor Crater laid the foundations for a detailed understanding of impact cratering. In the second half of our century it was mainly planetary exploration and extensive lunar research that led to the conclusion that essentially all craters visible on the Moon (and many on Mercury, Venus, and Mars) are of impact origin. From these observations it was concluded
that, over its history, the Earth had been subjected to a significant number of impact events. Part of the reason why this conclusion was not widely accepted among geologists was the obvious absence of large numbers of craters on the Earth's surface. The reason is of course that terrestrial processes (weathering, plate tectonics, etc.) effectively work to obliterate the surface expression of these structures on Earth. The science historian William Glen found, in an interesting historical and sociological evaluation of the K/T boundary debates, that "resistance to the [impact] hypothesis seemed inverse to familiarity with impacting studies." (Glen 1994, p. 52). Planetary scientists, astronomers, and meteoriticists, who deal on a daily basis with topics including asteroids and meteorites (products of collisions between asteroids), are used to view "large-body impact as a normal geological phenomenon - something to be expected throughout Earth history - but another group, the paleontologists, is confounded by what appears to be an ad hoc theory about a nonexistent phenomenon" (D. Raup in Glen 1994, p. 147). Thus, it seems that what is uniformitarian for a member of one scientific field (in this case a planetary scientist), would be considered by the representative of another field (e.g., paleontology) as an unnecessary deus ex machina. However, it is also important to take the time scales into account that are involved in this discussion. What geologists have called "uniformitarianism" is the result of a large number of individual catastrophes of various magnitudes over a sufficiently long time span. Earthquakes, volcanic eruptions, landslides, etc., are locally devastating during periods on the order of about 20 to 100 years, but if the whole world and longer time spans are taken into account, these (local) "catastrophes" become part of the (global) "uniformitarian" process of explosive volcanism, earthquake history, or erosion. The bias in what is considered uniformitarian is related to the life span of humans and the human civilization. As large meteorite impacts have not been observed during the last few millennia (with rare exceptions, such as the Tunguska event, which occurred in a remote Siberian location in 1908, but even this event was too small to produce a crater), such events tend to be neglected when constructing the "uniformitarian" history of the Earth. In contrast, small meteorites have been observed to fall from the sky quite frequently, but scientists have failed to make the connection to impact events by applying the same principle that is being used for extrapolating the frequency of volcanic eruptions and earthquakes: large and devastating ones occur less often than small events. There is no real conflict between uniformitarianism and meteorite impact. Over long periods of time, impact is a common process on the Earth. About 160 impact structures are currently (in the year 2000) known on Earth (e.g., Grieve and Shoemaker 1994; Grieve et al. 1995; updates are currently available on the internet, see web page of the Canadian Geological Survey at: http://gdcinfo.agg.emr.ca/toc.html?/crater/world_craters.html). A few of these structures were only recognized because layers of impact ejecta were found and eventually traced back to their source crater (e.g., Chicxulub, from studies of the K/T boundary impact layer). Considering that some impact events demonstrably affected the geological and biological evolution on Earth, and that even small
impacts can disrupt the biosphere and lead to local and regional devastation (Chapman and Morrison 1994), the understanding of impact structures and the processes by which they form should be of interest not only to earth scientists, but also to society in general.
1.2 General Characteristics of Impact Craters As no record seems to exist that documents the observation of a large impact event by humans over the last several thousand years (which is, of course, not a geologically long period of time), impact experiments and the detailed study of impact craters on Earth are indispensable for our understanding of these features. During an impact event, the target area is changed in a characteristic way, which can be used to help distinguish volcanic structures from meteorite impact craters. Meteorite impact craters are surficial features without deep roots, whereas in volcanic craters or calderas the disturbances continue to (or, rather, emerge from) great depth. Impact craters are almost always circular. On the Moon, with its surface covered by impact craters, only a small number of non-circular features are known. On Earth there axe also only few structures that result either from highly oblique impacts (see, e.g., the Rio Cuarto crater field in Argentina - Schultz et al. 1994), or from post-formational distortion due to, for example, tectonism or erosion (e.g., the Sudbury structure in Canada - e.g., St6ffler et al. 1994; Deutsch et al. 1995; or the Vredefort structure in South Africa - e.g., Reimold and Gibson 1996; Gibson and Reimold 2000). When discussing morphological aspects, one should note the distinction between an impact crater, i.e., the feature that results from the impact, and an impact structure, which is what we observe today, i.e., long after formation and modification of the crater. Impact craters (before post-impact modification by erosion and other processes) occur on Earth in two distinctly different morphological forms. These are known as simple craters (small bowl-shaped craters) with diameters of up to _<2 to 4 km, and complex craters, which are larger and have diameters of >2 to 4 km (the exact change-over diameter between simple and complex crater depends on the composition of the target). The striking morphological difference between the simple and complex craters is best illustrated by looking at lunar craters, where post-formational modification is minimal compared to crater structures on the Earth (e.g., Metosh 1989). Figs. 1.2.1 and 1.2.2 show a simple and a complex lunar crater, respectively. Complex craters axe characterized by a central uplift. Craters of both types have an outer rim and are filled by a mixture of fallback ejecta and material slumped in from the walls and crater rim during the early phases of formation. Such crater infill may include brecciated and/or fractured rocks, and impact melt rocks. Fresh simple craters have an apparent depth (crater rim to present-day crater floor) that is about one third of the crater diameter (Fig. 1.2.3). For complex craters, this value is closer to one fifth or one sixth. The central structural uplift in complex
craters consists o f a central peak or o f one or m o r e peak ring(s) and exposes rocks that are usually uplifted f r o m considerable depth. On average, the actual stratigraphic uplift amounts to about 0.1 of the crater diameter (e.g., M e l o s h 1989).
Fig. 1.2.1. Simple (bowl-shaped) impact crater on the Moon. Crater Isidorus D has a diameter of 15 km. (NASA Apollo 16 photo.)
Fig. 1.2.2. Complex impact crater on the Moon. Crater Theophilus has a diameter of about 100 km. The feature on the left is the antenna of the Apollo spacecraft. (NASA Apollo 16 photo.)
9
A
SIMPLE CRATER
B
COMPLEX CRATER
Fig. 1.2.3. Schematic cross-section through a simple (a) and a complex (b) impact crater. Ejecta around the crater rim are indicated by a stipple pattern, whereas brecciated, shocked, and melted crater fill rocks (including fallback ejecta) are indicated by larger open and filled irregular symbols. Fracturing beneath the crater floor is also indicated, as are the central stratigraphic uplift and a possible melt sheet in the complex crater case.
The variation in diameter of impact craters on Earth is quite different from that on (e.g.) the Moon, because on Earth basically all of the small craters axe relatively young. This size relationship is biased and results from typical terrestrial processes. The erosional processes that obliterate small (0.5-10 km diameter) craters after a few million years result in a severe deficit of such small craters, compared to the crater count that would be expected from the (observed) number of larger craters and from astronomical considerations (Grieve and Shoemaker 1994). This effect also explains why most small craters known on Earth are young. Older craters of larger initial diameter also suffer erosional degradation leading to the destruction of the original topographical expression, or to burial of
10
the structures under post-impact sediments. For details on crater morphology, see, e.g., Melosh (1989). On other planets and satellites (e.g., the Moon, Mercury, Mars, Ganymede, Callisto) larger structures than the simple and complex craters have been identified. These are the so-called multiring basins, which have diameters ranging from a few hundred to at least 2000 km (e.g., Spudis 1993). It is not clear if the largest impact structures known on Earth (e.g., Chicxulub with ca. 200 km diameter, or Vredefort with an initial diameter of possibly 300 km) may represent terrestrial examples of multiring basins or not. Some hypotheses have been formulated that call for the existence of terrestrial equivalents of lunar maria (Green 1972; Alt et al. 1988), which would be hundreds to thousands of kilometers in diameter, but no physical evidence supporting such far-reaching assumptions has yet been forthcoming.
1.3 Recognition of Impact Structures On the Moon and other planetary bodies that lack an appreciable atmosphere, impact craters can commonly be recognized from morphological characteristics. On the Earth, complications arise as a consequence of the obliteration, deformation, or burial of impact craters. Thus, it is ironical that despite the fact that impact craters on Earth can be studied directly in the field, they may be much more difficult to recognize than on other planets. This dilemma made it necessary to develop diagnostic criteria for the identification and confirmation of impact structures on Earth (see also French 1998). The most important of these characteristics are: a) crater morphology, b) geophysical anomalies, c) evidence for shock metamorphism, and d) the presence of meteorites or geochemical evidence for traces of the meteoritic projectile. Of these characteristics, only the presence of diagnostic shock metamorphic effects and, in some cases, the discovery of meteorites, or traces thereof, are generally accepted to provide unambiguous evidence for an impact origin. Shock deformation can be expressed in macroscopic form (shatter cones) or in microscopic form (see Sect. 1.6). The same two criteria apply to distal impact ejecta layers and allow to confirm that material found in such layers originated in an impact event at a possibly still unknown location. So far (2000), the presence of such evidence led to the confirmation of about 160 impact structures (some exposed on the surface, others are subsurface structures) on Earth (Fig. 1.3.1). The distribution of impact structures, as shown in Ng. 1.3.1, is not uniform over the planet. Even though about two thirds of the planet are covered by water, no impact structures have so far been found on the ocean floor. Only two structures are currently underwater, but are located on the continental shelf. There are several reasons for this: first, small projectiles make a crater in the ocean without penetrating through up to several kilometers of water and, therefore, do no leave a permanent imprint on the ocean floor. A good example is the Eltanin event, where
11
an asteroidal body impacted the Southern Ocean during the Late Ptiocene and only (partly melted) meteoritic debris was recovered from up to about 4 km water depth, but no crater was formed (e.g., Kyte and Brownlee t985; Kyte et al. 1988; Margolis et al. 1991; Gersonde et al. 1997). Only large bodies would leave a crater, but those are much rarer than small ones. Second, due to plate tectonics, the ocean floor is relatively young (less than about 200 Ma), and records only recent impact events. Third, the ocean floor has never been searched in any detail for evidence of impact events, and even if indications are found, structures on the deep ocean floor are very difficult to reach and explore. The distribution of impact craters on land is largely governed by two factors: age of target areas and efficiency of crater search programs. Among the young craters there is a predominance of relatively recent, small structures (which are mostly simple craters), because erosion either removes or rapidly covers other craters (Figs. 1.3.2 and
1.3.3). Whereas petrographical and geochemical data can provide confirming evidence for impact, morphological and geophysical observations are important in providing supplementary (or initial) information. Geological structures with a circular outline that are located in places with :no other obvious mechanism for producing near-circular features may be of impact origin and at least deserve further attention. Geophysical methods are also useful in identifying candidate sites for further studies, especially for subsurface features. In complex craters the central uplift usually consists of dense basement rocks and usually contain severely shocked material. This uplift is often more resistant to erosion than the rest of the crater, and, thus, in old eroded structures the central uplift may be the only remnant of the crater that can be identified. Geophysical characteristics of impact craters include gravity, magnetic properties, reflection and refraction seismics, electrical resistivity, and others (see Pilkington and Grieve 1992, and Grieve and Pilkington 1996, for reviews). In general, simple craters have negative gravity anomalies due to the lower density of the brecciated rocks compared to the unbrecciated target rocks, whereas complex craters often have a positive gravity anomaly associated with the central uplift that is surrounded by an annular negative anomaly. Magnetic anomalies can be more varied than gravity anomalies. Seismic data often show the loss of seismic coherence due to structural disturbance, slumping, and brecciation. Such geophysical surveys are important for the recognition of anomalous subsurface structural features, which may be deeply eroded craters or impact structures covered by post-impact sediments (e.g., Chicxulub - see Hildebrand et al. 1991; or in the U.S.: Ames, Avak, Chesapeake Bay, Manson, Newporte, Red Wing Creek see Koeberl and Anderson 1996a, b, for reviews). No book or review publication currently exists that gives detailed descriptions of all impact structures known on the Earth, with the possible exception of Hodge (1994), who gives a short, but unfortunately rather uneven and incomplete, overview of all impact structures. There are some more detailed reviews of impact structures in some geographical areas, e.g., Africa (Koeberl 1994a), Australia (Glikson 1996; Shoemaker and Shoemaker 1996), northern Europe (Pesonen
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13
Fig. 1.3.2. The Roter Kamm crater in Namibia, an example of a relatively young (3.7 Ma) simple impact crater (2.5 km diameter), which is already suffering from erosion and is mostly covered by aeolian sediments.
Fig. 1.3.3. Gosses Bluff impact structure, Australia. This complex impact structure is 142.5 million years old and severely eroded. The inner ring has a diameter of about 5 to 6 km and is the remnant of the central uplift. A faint circular feature, notable from drainage patterns, with a diameter of 22 km, outlines the original diameter of the crater. The original crater rim itself has long since been removed by erosion, leaving only the prominent central uplift behind. Space Shuttle photograph $84-14-41-028; north is to the left.
14
1.4 Formation of Impact Craters Impact craters form when a small object (in the solar system) collides with a large one. For a planet like the Earth, the impacting small bodies are derived either from asteroidal or cometary sources. From observational programs that study the orbits of asteroids and comets, astronomers have a relatively good understanding of the rate at which these objects strike the Earth (e.g., Shoemaker et al. 1990; Weissman 1990). For example, minor objects in the solar system with diameters of about 1 km (mainly asteroids) collide with the Earth at a frequency of about 4.3 impacts per million years (Shoemaker et al. 1990). Depending on the impact velocity and angle, each such impact is capable of forming a crater with a diameter of at least 10 km. Impactors about 2 km in diameter collide with the Earth about every 12-106 years. Collisions of Earth-orbit crossing asteroids with the Earth dominate the formation of craters that are smaller than about 30 km in diameter, whereas cometary impacts are probably responsible for the majority of craters with diameters of more than about 50 km (Shoemaker et al. 1990). However, the orbits of asteroids are better known than those of comets, because many of the latter have such long periodicities that no appearance has yet been observed during the time of human civilization. Thus, the long-term orbital evolution of asteroids is better known than that of comets, and collisions with asteroids could be calculated longer in advance than those with comets (which may be known only a few months in advance if a comet approaches from the outer reaches of the solar system). The formation of a crater by hypervelocity impact is - not only in geological terms - a very rapid process that is usually divided into three stages: 1) contact/compression stage, 2) excavation stage, and 3) post-impact crater modification stage. Crater formation processes have been studied for many decades, but space limitations and the focus of this book on impact ejecta require that the reader is referred to the literature (see, e.g., Gault et al. 1968; Roddy et al. 1977; Melosh 1989; and references therein) for more detailed discussions of the physical principles of impact crater formation. Here, we mention only some basic principles. During the impact of a large meteorite, asteroid, or comet, large amounts of kinetic energy (equal to 1/2mv,2 m = mass, v = velocity) are released. Earlier in the century, the amount of energy was largely underestimated, because the velocities with which extraterrestrial bodies hit the Earth had not been known or assessed properly. This is shown very well by the historical development of Meteor Crater studies (see Hoyt 1987; Mark 1987), where the mass of the body that created the crater was originally severely overestimated. Any extraterrestrial body that is not slowed down by the atmosphere will hit the Earth with a velocity between about 11 and 72 km/s. These velocities are determined by celestial mechanics: 11 km/s is the escape velocity of the Earth-Moon system, to which a body with zero velocity difference to this system will be accelerated simply by gravitational attrac-
15
tion; 72 km/s is the sum of the escape velocity of the solar system at the distance of 1 Astronomical Unit (A.U.; approximately equal to the average distance of the Earth from the Sun), 42 km/s, and the average orbital velocity of the Earth, 30 km/s. Thus, every body that collides with the Earth, will do so at cosmic velocity. The Earth accretes about 100 tons of extraterrestrial material every day, but most of that is in the form of dust. Larger dust grains may, when they hit the Earth's atmosphere, burn up and cause a glowing channel of ionized air: a shooting star or meteor (before entering the Earth's atmosphere, a small interplanetary body is called a meteoroid). Such bodies will be decelerated in the atmosphere until they reach free-fall velocity; during this deceleration they may lose a large fraction of their mass. If a remnant of a small extraterrestrial body reaches the surface of the Earth intact, it is called a meteorite. These may hit the surface with appreciable speed (but much less than cosmic velocity) and cause penetration craters or penetration funnels. The largest single-mass meteorite currently known on Earth, which survived passage through the atmosphere and the "hard landing", is the Hoba iron meteorite in Namibia with about 60 tons. In contrast, if a body is large enough to not be decelerated significantly in the Earth atmosphere and hits the surface with cosmic velocities, it will produce a hypervelocity impact crater. For the purposes of this book the term impact or impact crater is always meant to be the result of a hypervelocity impact. The physical processes that govern the formation of an impact crater are the result of the extremely high amounts of energy that are liberated almost instantaneously when the projectile (also termed impactor, bolide, meteorite, asteroid, comet [nucleus]) hits the ground. Even a small meteoritic body, about 6 m in diameter, would release as much energy as an atomic bomb when it hits the surface of the Earth at about 20 km/s (about 20 kilotons of TNT, or about 8.3.10 ~3joules [J]). A meteorite with a diameter of 250 m has a kinetic energy that is roughly equivalent to about 1000 megatons of TNT, which would lead to the formation of a crater about 5 km in diameter. The relatively small Meteor (or Barringer) Crater in Arizona (1.2 km diameter) was produced by an iron meteorite of about 30-50 m in diameter and had an energy content of more than 10 megatons of TNT (see Schnabel et al. 1999). There is a difference between the behavior of a stony impactor and an iron one. Due to the difference in mechanical strength, smaller iron meteorites can reach the ground intact, in contrast to stony meteorites, which may undergo catastrophic disintegration in the atmosphere. In 1908, a stony bolide exploded over the Tunguska region in central Siberia (see Fig. 1.3.1) and devastated more than 2000 km 2 of forest (see, e.g., Turco et al. 1982, and Martino et al. 1998, for reviews). It has been estimated that a stony body with a diameter of about 20 to 40 m exploded (due to stress during deceleration) at an altitude of about 10 km, liberating an amount of energy equivalent to about 10 to 30 megatons of TNT; the body was totally disintegrated (see, e.g., Chyba et al. 1993; Svetsov 1996). Events of such magnitude may happen every few hundred years somewhere over the Earth (e.g., Chapman and Morrison 1994).
16
The impact energy can be compared to that of "normal" terrestrial processes, such as volcanic eruptions or earthquakes. During a small impact event, which may lead to craters of 5-10 km in diameter, about 102~25 ergs (1017 18 j) are released, whereas during formation of larger impact craters (<50 km in diameter) about 1028-3°ergs (1021-23J) are liberated (e.g., French 1968, 1998; Kring 1993). On the other hand, about 6.1023 ergs (6.1016 J) were released over several months during the 1980 eruption of Mount St. Helens, and 1024 ergs (1017 J) in the big San Francisco earthquake in 1906. It may also be surprising that the total annual energy release from the Earth (including heat flow, which is by far the largest component, besides contributions from volcanism and earthquakes) is about 1.3.1028 ergs (1.3-102' J/y) (French 1998; Sclater et al. 1980; Morgan 1989). This amount of energy is comparable to the energy that is released within a very short time interval during large impact events. It is also important to realize that the energy that is liberated during an impact is concentrated in a point on the Earth's surface, leading to an enormous local energy increase. The collision of a medium-sized asteroid or cometary nucleus would, therefore, release the same amount of energy within seconds that the whole Earth releases within hundreds or thousands of years.
1.5 Shock Waves and the Stages of Crater Formation Structural modifications and phase changes in the target rocks occur during the compression stage, whereas the morphology of a crater is defined in the second and third stages of impact cratering. For a more detailed description of crater formation, see, e.g., Grieve (1987, 1991), Melosh (1989), Boslough and Asay (1993), Melosh and Ivanov (1999), and references therein. During this early impact phase, the impacting body is stopped at a depth equivalent to about two projectile radii and the kinetic energy (1/2mv2) is transformed into heat and shock waves that penetrate into the projectile and target. The most important phenomenon, which is characteristic of impact, is the generation of a supersonic shock wave that is propagated into the target rock. The effects of shock waves on matter are well understood from decades of experimental study. The following discussion is based mainly on information from Melosh (1989). Matter is being accelerated very rapidly and, as a consequence of the decrease of compressibility with increasing pressure, the resulting stress wave will become a shock wave moving at supersonic speed (up to about 2/3 of the impact velocity). Shock waves are inherently nonlinear and shock fronts are abrupt. They can be mathematically represented as a discontinuous increase of pressure, defisity, particle velocity, and internal energy. In reality, shock waves have a finite thickness, which is, however, very limited. For example, the widths of shock waves in gas are limited to about 10 gm, which is roughly equal to one molecular mean free path, but shock waves in solids are wider, up to a few meters in rocks, depending on their porosities.
17
The shock wave leads to compression of the target rocks at pressures far above a material property called the Hugoniot elastic limit. The Hugoniot elastic limit (HEL) is usually described as the maximum stress in an elastic wave that a material can be subjected to without permanent deformation (Melosh 1989). Above this limit, plastic, or irreversible, distortions occur in the solid medium through which the compressive wave travels (see, e.g., compilations by Roddy et al. 1977; Melosh 1989; and references therein). The value of the HEL is about 5-10 GPa for most minerals and whole rocks. For example, single crystals of quartz have HELs ranging from 4.5 to 14.5 GPa (depending on the orientation of the crystals), for feldspar the HEL is at 3 GPa, and for olivine at 9 GPa. For rocks, the HEL of dolomite is 0.3 GPa, for granite 3 GPa, and for granodiorite, 4.5 GPa. The only known process that produces shock pressures exceeding the HELs of most crustal rocks and minerals in nature is impact cratering. The pressures reached in volcanic processes are not known to exceed 0.5 to 1 GPa (see, e.g., Gratz et al. 1992b). In addition to structural changes, phase changes may occur in minerals once the HEL is exceeded. For a thermodynamic description of shock fronts travelling through matter, the so-called Hugoniot equations are used (see Melosh 1989). These equations link the pressure P, internal energy E, and density p ahead of a shock wave (uncompressed: P0, E0, P0) to values behind the shock front (compressed: P, E, p). The density is also expressed as the specific volumes V = 1/p and V 0 = l/p0 for the compressed and uncompressed cases, respectively. Initial pressure, energy, and density ahead of the shock are known values, whereas the respective values behind the shock are unknown quantities, as are the shock velocity U and particle velocity up behind the shock front. The Hugoniot equations are then written as: p(U - u ) = poU P - Po = poUy E - E 0 = (P + P0)(V0 - V)/2 These equations express the conservation of mass, momentum, and energy across the shock front to reduce the number of unknown variables from five to two. For a derivation of the Hugoniot equations, see Appendix 1 in Melosh (1989), as well as Strffler (1972) and Boslough and Asay (1993). In the uncompressed material, the initial particle velocity should be zero, and the initial pressure P0 can be neglected, yielding the approximation E - E 0 = up2/2. In addition to the three equations mentioned above, a fourth one, the so-called equation of state, is necessary to specify conditions on either side of the shock front. This equation links pressure, specific volume (density), and internal energy: P = (V,E). Equations of state have been determined experimentally for a large number of different materials (e.g., Marsh 1980). The shock wave equation of state data can be plotted in pressure versus specific volume or shock velocity versus particle velocity diagrams (Fig. 1.5.1). The curves in these diagrams are not equivalent to conventional equilibria in thermo-
18
dynamical pressure versus volume (P,V) diagrams, but represent the loci of seve r n individual shock events, i.e., each point on a curve is the result of one particular shock wave compression event. The HEL appears as a kink in the shock curve, indicating yielding at the maximum stress of the elastic wave.
Hugoniot Equation of State Curve Curve showing the loci of shock events
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Elas!ic
PHEL Elastic Wave - - - ~
Vo Specific Volume (V) Fig. 1.5.1. Hugoniot equation of state curve. The Hugoniot curve does not represent a continuum of states as in thermodynamical diagrams, but the loci of individual shock compression events. The yielding of the material at the Hugoniot Elastic Limit is indicated (diagram after Koeberl 1997a).
After the passage of the shock wave, the high pressure is released by a so-called rarefaction wave (also called release wave), which follows the shock front. The rarefaction wave is a pressure wave, not a shock wave, and travels at the speed of sound in the shocked material. The release wave moves faster than the shock wave
19
and, therefore, gradually overtakes the shock front and causes a decrease in pressure with increasing distance of propagation. Whereas the pressure behind a rarefaction wave may drop to near zero, the residual particle velocity actually accelerates material, leading to impact crater excavation. In addition, the rarefaction wave not only conserves mass, energy, and momentum (as the shock wave does), but also entropy. Thus, rarefaction is a thermodynamically reversible adiabatic process, whereas shock compression is thermodynamically irreversible. During shock compression, a large amount of energy is being introduced into a rock. Upon decompression, the material follows a release adiabat in a pressure versus specific volume diagram. The release adiabat is located close to the Hugoniot curve, but usually at somewhat higher P and V values, leading to excess heat appearing in the decompressed material, which may result in phase changes (e.g., melting or vaporization). Because the pressure in the shock waves are so high, the release of the pressure (decompression) results in almost instantaneous melting and vaporization of the projectile - and of large amounts of target rocks. All the effects of the phenomena described above can be observed in various forms in shocked minerals and rocks, and form during the contact (or compression) stage, which only lasts up to a few seconds even for large impacts. The contact stage is followed by the excavation stage, in which the actual crater is excavated. Complex interactions between the shock wave(s) and the target, as well as the release wave(s), lead to an excavation flow. In the upper levels of the target, material moves mainly upwards and out, whereas in lower levels material moves mainly down and outwards, which results in a bowl-shaped depression, the transient cavity. This cavity grows in size as long as the shock and release waves are energetic enough to excavate materials from the impact location. Afterwards, gravity and rock-mechanical effeCts lead to a collapse of the steep and unstable rims of the transient cavity, widening and filling of the crater. Compared to the contact stage, the excavation stage takes longer, but still only up to a minute or two even in large craters of more than 200 km diameter. Thus, the formation of an impact crater can be summarized schematically as shown in Fig. 1.5.2. First, a relatively small extraterrestrial body hits the surface (A) with cosmic velocity and marks the beginning of the contact and compression stage. Next (B), jetting ejects material from the impact site with velocities that can approach about one half of the impact velocity. A shock wave propagates hemispherically into the ground (C), closely followed by a rarefaction wave, which releases the shock pressure from the compressed rocks and leads to the creation of a mass flow that opens up the crater (D), marking the beginning of the excavation phase. The maximum excavation is reached in (E), showing the extent of the transient cavity. The post-impact modification stage is characterized by enlargement of the transient crater through slumping of the crater walls and infill from fallback ejecta (F). More details can be found in French (1998) and Melosh (1989). Most ejecta end up close to the crater (<5 crater radii), but a small fraction may travel much greater distances (see Sect. 2.1).
20
B
A
d • ".
..
.:.'.
-
:='..:.':.L
,
-:-'..
,
.
? .
".: .......
' . -
.:
.
~
-'.':
; . : , I .
-".
o
C
-..
.-
\
"
-
:
.'
/
• -
.
• .
/
\
E
• •
o °
~ •
o
~
.
F
o
•
°
e
•
o
•
•
•
•
.
P
" ,
Fig. 1.5.2. Schematic diagram of the stages of the formation of a simple impact crater.
Only small craters on Earth (up to about 2 to 4 km in diameter, depending on the target rock type) are simple bowl-shaped craters. These have a depth to diameter ratio of about 1:5. Larger impact events lead to the formation of complex craters, which have central peaks, wall terraces, and (in the largest structures) internal rings. The formation of the central peak (or central uplift) is not well understood. Theoretical studies (e.g., Melosh 1989; Melosh and Ivanov 1999) indicate that the central uplift forms within minutes by rebound and a series of
21
complicated rock movements and deformations (during the collapse of the transient cavity) that may involve a process called acoustic fluidization (cf. Melosh and Ivanov 1999). This process leads to the stratigraphic uplift of rock strata well above their normal stratigraphic positions. Thus, the formation of large (more than 100km in diameter) impact structures leads to the (vertical) stratigraphic uplift of material at the center of the structure by about 10 kin. The result is a often a geological and/or metamorphic anomaly, which draws attention to the structure (e.g., Gibson and Reimold 2000). The central uplift is usually a geologically stable feature that remains, in some cases (e.g., Vredefort, Gosses Bluff), as the only remnant of the impact crater after long periods of erosion. Moreover, the rocks of the central uplift have been subjected to high shock pressures. This allows the use of rocks from the (eroded) central uplift in the identification of a structure as being of impact origin.
1.6 Shock Metamorphic Effects 1.6.1 General A large meteorite impact will produce shock pressures of >100 GPa and temperatures >3000°C in large volumes of the target rock. These conditions are in sharp contrast to conditions for endogenic metamorphism of crustal rocks, with maximum temperatures of 1200°C and pressures of usually <2 GPa (except static pressure affecting some deep-seated rocks, e.g., eclogites) (Fig. 1.6.1. l). As mentioned above, shock compression is not a thermodynamically reversible process, and most of the structural and phase changes in minerals and rocks are uniquely characteristic of the high pressures (5->50 GPa) and extreme strain rates (106-108 s-1) associated with impact. Some assemblages of high-pressure and high-temperature mineral phases are preserved together with glass in shocked rocks due to disequilibrium caused by transient high pressures followed by quenching. As some recent debates indicate (e.g., Lyons et al. 1993 and Luczaj 1998, and the counter-arguments by Reimold 1994 and Koeberl and Reimold 1999), there seems still to be some incomplete understanding in the geological community about the precise nature of shock metamorphism (for a discussion, see, e.g., French 1990a; Sharpton and Grieve 1990). In contrast to some assertions, the existence of definite shock metamorphic features in volcanic rocks has never been substantiated (see, e.g., de Silva et al. 1990; Gratz et al. 1992b). Static compression (see, e.g., Kingma et al. 1993), as well as volcanic or tectonic processes, yield products different from those of shock metamorphism, because of lower peak pressures and especially strain rates that are different by more than 11 orders of magnitude. It must be reaffirmed that the study of the response of materials to shock is not a recent development, but has been the subject of thorough investiga-
22
tions over much of the 20th century, in part stimulated by military research. Numerous shock recovery experiments (i.e., controlled shock wave experiments, which allow the collection of shocked samples for further studies), using various techniques, have been performed. These experiments have led to a good understanding of the conditions for formation of shock metamorphic products and a pressure-temperature calibration of the effects of shock pressures up to about 100 GPa (see, e.g., H6rz 1968; French and Short 1968; St6ffier 1972, 1974; Gratz et al. 1992a, b; Huffman et al. 1993; St6ffler and Langenhorst 1994; Huffman and Reimold 1996; Langenhorst and Deutsch 1998; and references therein).
Temperature (°C)
"i ,--L
"
==
•' " \ K"
............ .o.~.~..~
9= Shatter Cones O
~ " ........
• ......
"~ "~ ~" ~ . . . . Coesite
_\ Planc~r Dreesformation ---~~Dt~l~c
Graph/re Oiamo~
Stishovite
Glass
o=
Melt ...& Q 0
Vapor
Fig. 1.6.1.1. Comparison of pressure-temperature fields of endogenic metamorphism and shock metamorphism. Also indicated are the onset pressures of various irreversible structural changes in the rocks due to shock metamorphism. The curve on the right side of the diagram shows the relation between pressure and post-shock temperature for shock metamorphism of granitic rocks (after Grieve 1987, and B.M. French, personal communication, 1995).
23
0 I
10 I
20 I
30 I
40 I
50 I
60 I
Shock Stages 0
I
la
<---__
,b
I"
= ~ -
I Planar
•_._•
Planar
~
','
I
Fractures DeformationFeatures
Mosaicism DiaplecticGlass\ Lechatelierite
< 0 I
10 I
Stishovite~ ~ _ _ 20 I
30 I
40 I
Coesite 50 I
60 I
Shock Pressure in GPa Fig. 1.6.1.2. Pressure dependency of various characteristic shock indicators in quartz, and relation to shock stages (after Strffler and Langenhorst 1994).
A wide variety of shock metamorphic effects has been identified (Fig. 1.6.1.2). The best diagnostic indicators for shock metamorphism are features that can be studied easily by using the polarizing microscope. They include planar microdeformation features, optical mosaicism, changes in refractive index, birefringence, and optical axis angle, isotropization (e.g., formation of diaplectic glasses), and phase changes (high pressure phases; melting). Kink bands (mainly in micas) have also been described as a result of shock metamorphism (e.g., Hrrz and Ahrens 1969), but can also be the result of normal tectonic deformation. Although there seem to be some differences between the characteristics of the kink bands formed by shock and those formed in "normal" deformations (Strffler 1972), these have not been quantified. Table 1.6.1.1. lists the most characteristic products of shock metamorphism, as well as the associated diagnostic features.
24
Table 1.6.1.1. Characteristics and formation pressures of various shock deformation features. Pressure (GPa)
Features
Target Characteristics
Feature Characteristics
2-45
Shatter cones
Best developed in homogeneous finegrained, massive rocks.
Conical fracture surfaces with subordinate striations radiating from a focal point.
5-45
Planar fractures and Planar deformation features (PDFs)
Highest abundance in crystalline rocks; found in many rock-forming minerals; e.g., quartz, feldspar, olivine and zircon.
PDFs: Sets of extremely straight, sharply defined parallel lamellae; may occur in multiple sets with specific crystallographic orientations.
30-40
Diaplectic glass
Most important in quartz and feldspar (e.g., maskelynite from plagioclase).
Isotropization through solid-state transformation under preservation of crystal habit as well as primary defects and sometimes planar features. Index of refraction lower than in corresponding crystal but higher than in fusion glass.
15-50
High-pressure polymorphs
Quartz polymorphs most common: coesite, stishovite; but also ringwoodite from olivine, and others.
Recognizable by crystal parameters, confirmed usually with XRD or NMR; abundance influenced by post-shock temperature and shock duration; stishovite is temperature-labile.
> 15
Impact diamond
From carbon (graphite) present in target rocks;
Cubic (hexagonal?) form; usually very small but occasionally up to ram-size; inherits graphite crystal shape.
rare.
45->70
Mineral melts
Rock-forming minerals (e.g., lechatelierite from quartz).
Impact melts are either glassy (fusion glasses) or crystalline; of macroscopically homogeneous, but microscopically often heterogeneous composition.
Data from: Alexopoulos et al (1988), French and Short (1968), Sharpton and Grieve (1990), Strffler (1972, 1974), Koeberl (1994), Koeberl et al. (1995a).
Before discussing the various shock metamorphic features, the type and location of impact lithologies should be briefly m e n t i o n e d (however, see Sect. 1.7 for details). In an impact crater, shocked minerals, impact melts, and impact glasses are c o m m o n l y found in various impact-derived breccias (e.g., Fig. 1.6.1.3). Wellpreserved ejecta at the crater rim m a y display a stratigraphic sequence that is inverted compared to the normal stratigraphy in the area. The impact process leads to the formation of various breccia types, which are found within and around the resulting crater (see also Strffier and Grieve 1994a, b, and Koeberl et al. 1996a). The three m a i n breccia types include
25
monomict or polymict breccias consisting of 1) cataclastic (fragmental), 2) suevitic (fragmental with a melt fragment component), or 3) impact melt (melt breccia - i.e., melt in the matrix - with a clastic component) breccias. The breccias can be allochthonous or autochthonous. In addition, dikes of injected or locally formed fragmental or pseudotachylitic breccias (Reimold 1995, 1998), which contain evidence of melting, can be found in the basement rocks. Whether these various breccia types are indeed present and/or preserved in a crater depends on factors including the size of the crater, the composition, and the porosity of the target area (e.g., Kieffer 1971; Kieffer and Simonds 1980), and the level of erosion (see, e.g., Roddy et al. 1977; H r r z 1982; H r r z et al. 1983; Grieve 1987; and references therein).
Fig. 1.6.1.3. Macroscopic view of a granitic fragmental breccia from the Newporte impact structure, North Dakota; sample D9463.0 from the Duerre 43-5 drill core (from 2884 m depth), showing angular granitic fragments in a dark, fine-grained, clast-rich matrix.
1.6.2 Shatter Cones The occurrence of shatter cones has long been discussed as the only good macroscopic indicator of impact-generated deformation, and a variety of structures were
26
proposed to be of impact origin on the basis of shatter cone occurrences (e.g., Dietz 1968; Milton 1977). Such cones have also been formed in (chemical) explosion crater experiments (see, e.g., Milton 1977). Their formation is dependent on the type of target rock (i.e., they are better developed in certain lithologies than in others), and has been estimated to take place at pressures in the range of 2 to 45 GPa (e.g., Gash 1971; Milton 1977). In general, shatter cones are cones with regular thin grooves (striae) that radiate from the top (the apex) of a cone. They can range in size from less than one centimeter to more than one meter (Fig. 1.6.2.1).
Fig. 1.6.2.1. Shatter cone from the Haughton Dome (Devon Island, Canada); size of sample about 20 cm long dimension.
Shatter cones occur mostly in the central uplift and in outer and lower parts of a crater and may be preserved even if a structure is deeply eroded. Unfortunately, conclusive criteria for the recognition of "true" shatter cones have not yet been defined. It is possible to confuse impact-produced cones with concussion features, pressure-solution features (cone-in-cone structure), or abraded or otherwise striated features with shatter cones (Reimold and Minnitt 1996). It would be important to arrive at some generally accepted criteria for the correct identification of shatter cones, as some impact craters have been identified almost exclusively by
27
the occurrence of shatter cones (for example, the Red Wing Creek structure, USA; see Koeberl et al. 1996b and the compilation by Koeberl and Anderson 1996b). Shatter cones form in a variety of target rocks, including crystalline igneous and metamorphic rocks, sandstones, shales, and carbonates. The best developed cones are found in fine-grained rocks, especially carbonates (e.g., limestone). The formation mechanism of shatter cones is poorly understood. It seems that although the shatter cones themselves form at fairly low shock pressures, localized melting on shatter cone surfaces requires locally higher pressures and/or temperatures. The apices of shatter cones have also been used, after graphical restoration to their original horizontal preimpact position, to reconstruct the source of the shock wave (e.g., Dietz 1968; see discussion in French 1998, pp 38-40). However, there can be some confusion about the orientation of shatter cones, with multiple apex directions even within one unit, as shown in Fig. 1.6.2.1, making any reconstruction of shock wave sources impossible. Nevertheless, shatter cones are important as potential macroscopic shock indicators, as they are developed in large volumes of rock, and are useful as a guide for the possible presence of more definitive shock indicators, such as shocked minerals (see below).
1.6.3 Mosaicism Mosaicism is a microscopic expression of shock metamorphism observed in a number of rock-forming minerals (e.g., H6rz and Quaide 1972) and appears as an irregular mottled optical extinction pattern, which is distinctly different from undulatory extinction that, for example, occurs in tectonically deformed quartz. Mosaicism can be measured in the optical microscope by determining the scatter of optical axes in different regions of crystals showing mosaicism. Mosaicism can be semiquantitatively defined by X-ray diffraction study of the asterism of single crystal grains, where it shows up as a characteristic increase (with increasing shock pressure) of the width of individual lattice diffraction spots in diffraction patterns. Highly shocked quartz crystals show a diffraction pattern that becomes similar to a powder pattern, because of shock-induced polycrystallinity. Many shocked quartz grains that show planar microstructures also show mosaicism. In addition, it should be noted that the crystal lattice of shocked quartz shows lattice expansion above shock pressures of 25 GPa, leading to an expansion of the cell volume by <3% (Langenhorst 1994).
1.6.4 Planar Microstructures Two types of planar microstructures can be apparent in shocked minerals: planar fractures (PFs) and planar deformation features (PDFs). Their characteristics are summarized for the example "quartz" in Table 1.6.4.1. PDFs in rock-forming minerals (e.g., quartz, feldspar, or olivine) are generally accepted to provide diagnostic evidence for shock deformation (see, e.g., French and Short 1968; StOffler
28
1972, 1974; Alexopoulos et al. 1988; Sharpton and Grieve 1990; Strffier and Langenhorst 1994; Huffman and Reimold 1996; Grieve et al. 1996). PFs, in contrast to irregular, non-planar fractures, are thin fissures, spaced about 20 p m or more apart, which are parallel to rational crystallographic planes with low Miller indices, such as (0001) or {1011} (e.g., Engelhardt and Bertsch 1969). PFs form at lower pressures than PDFs, and may not provide conclusive evidence of shock metamorphism, but can direct attention to other, more characteristic, shock deformation effects.
Table 1.6.4.1. Characteristics of planar fractures and planar deformation features in quartz. Nomenclature
1. 2.
Planar fractures (PF) Planar deformation features (PDF) 2.1 Non-decorated PDFs 2.2 Decorated
Crystallographic orientation
1. PFs: usually parallel to (0001) and {1011} 2. PDFs: usually p to {1013}, {..10]2},_{10]1}, (0001), {1122}, {1121}, {1010}, {1120}, {2131}, {5161}, etc.
Optical microscope properties
Multiple sets of PFs or PDFs (up to 15 orientations) per grain Thickness of PDFs: <2-3 gm Spacing: >15 p.m (PFs), 2-10 ~tm (PDFs)
TEM properties (PDFs)
Two types of primary lamellae are observed: 1. Amorphous lamellae with a thickness of ca. 30 nm (at pressures <25 GPa) and ca. 200 nm (at pressure >25 GPa) 2. Brazil twin lamellae parallel to (0001)
Data after Strffler and Langenhorst (1994).
PDFs, together with the somewhat less definitive planar fractures (PFs), are well developed in quartz (Strffier and Langenhorst 1994). PDFs are parallel zones with a thickness of <1-3 g m and are spaced about 2 - 1 0 g m apart (see Figs. 1.6.4.1a, b). The degree of planarity of the individual sets of PDFs is an important parameter for the correct identification of bona fide PDFs and allow their distinction from (sub-)planar features that are produced at lower strain rates, e.g., in tectonically deformed quartz. Tectonic deformation lamellae ( B r h m lamellae) usually consist of bands that are >10 I.tm wide and are spaced at distances of >10 gm. They are usually not completely straight, do not extend through the whole grain, and occur only in one set. As such they can easily be, with some experience, distinguished from PDFs. It was demonstrated from Transmission Electron Microscopy (TEM) studies (see, e.g., Goltrant et al. 1991) that PDFs consist of amorphous silica. The structural state of the glassy lamellae is, however, slightly different from that of regular
29
silica glass (Goltrant et al. 199l, 1992). The fact that the PDF lamellae are filled by glass allows them to be preferentially etched by, e.g., hydrofluoric acid, emphasizing the planar deformation features (see Fig. 1.6.4.2). Such an etching method has been described by Gratz et al. (1996) and can be used, in combination with SEM studies, to distinguish tectonically deformed quartz from shocked quartz. Engelhardt and Bertsch (1969) have classified PDFs into four groups: (a) nondecorated PDFs (extremely fine lamellae, cannot be resolved in the optical microscope), (b) decorated PDFs (the lamellae are lined by, or replaced with, small spherical or elliptical bubbles, often representing fluid inclusions), (c) homogeneous lamellae (thicker lamellae that can be resolved in the microscope), and (d) filled PDFs (where the lamellae are filled with very small fine-grained crystals). Types (a) and (b) are the most common ones. In addition, TEM studies have shown that there is a second type of PDF, which consists of very thin multiple lamellae of Brazil twins. Brazil twins have been observed in hydrothermally grown quartz, but always parallel to the {1011} plane, while the impact-derived Brazil twins form at pressures >8 GPa, are of mechanical origin, and are exclusively formed parallel to the (0001) plane (Goltrant et al. 1991, 1992; Leroux et al. 1994). The latter authors have documented that such Brazil twins are recognizable from the Vredefort impact structure in South Africa because they are more resistant to annealing than other shock metamorphic indicators. Most rock-forming minerals, as well as accessory minerals, such as zircon, develop PDFs (e.g., St6ffier 1972, 1974; Dworak 1969). The occurrence of diagnostic shock features is by far the most important criterion for evaluating the impact origin of a crater, particularly when several of the features that are typical of progressive shock metamorphism, as listed in Table 1.6.1.1, have been found. The occurrence of PDFs and PFs can be used, together with other shock effects, to determine the maximum shock pressure in impactites (Table 1.6.4.2). Most commonly, quartz is used to study these shock effects, as it is the simplest, best studied, and most widely distributed rock-forming mineral that develops PDFs well. Planar deformation features occur in planes corresponding to specific rational crystallographic orientations. In quartz, the most abundant mineral that develops distinctive PDFs, the (0001) or c (basal), {1013} or co, and {1012} or ~ orientations are the most common ones. In addition, PDFs often occur in more than one crystallographic orientation per grain. With increasing shock pressure, the distances between the planes decrease, and the PDFs become more closely spaced and more homogeneously distributed over the grain, until at about >35 GPa complete isotropization has been achieved. Depending on the peak pressure, PDFs are observed in 2 to 10 (maximum 18) orientations per grain. To properly characterize PDFs, it is necessary to measure their crystallographic orientations by using either a universal stage (Reinhard 1931; Emmons 1943) or a spindle stage (Medenbach 1985), or by transmission electron microscopy (see, e.g., Goltrant et al. 1991; Gratz et al. 1992a; Leroux et al. 1994).
30
,,3
2-~"
~
-
Fig. 1.6.4.1. (a) PDFs in quartz from the Ilyinets impact structure, Ukraine (photo courtesy W.U. Reimold)• (b) PDFs in feldspar from the K/T boundary, Raton Basin (photo courtesy B.F. Bohor, U.S. Geological Survey)•
31
Fig. 1.6.4.2. SEM image of quartz grain from the K/T boundary layer at DSDP Site 596 (Southwest Pacific), after brief etching with HF, showing three different sets of PDFs (courtesy B.F. Bohor, U.S. Geological Survey).
The relative frequencies of the crystallographic orientations of PDFs can be used to calibrate shock pressure regimes, as given in Table 1.6.4.2 (see, e.g., Robertson et al. 1968; H6rz 1968; StOffler and Langenhorst 1994). For example, at 5 to 10 GPa, PDFs with (0001) and {1011} orientations are formed, whereas PDFs with {1013} orientations start to form between about 10 and 12 GPa. Such studies are done by measuring the angles between the c-axis and a set of PDFs in individual quartz grains with a universal stage. In a stereographic projection (see Engelhardt and Bertsch 1969), the optical axis (c-axis) is rotated into the center of projection, the locations of the poles of PDFs are plotted, and then those positions are compared with the stereographic projection of the rational crystallographic planes in quartz (see Sect. 6.3.5). The measured angles that fall within 5 ° of the theoretical polar angle of the plane are considered valid and can be indexed. The results of this procedure can be shown in the form of a histographic plot of indexed PDFs. Such plots are used to identify the relative frequencies, in which the various shock-characteristic crystallographic orientations occur.
32
Table 1.6.4.2. Relation between shock stage and crystallographic orientation (indices) of planar microstructures in quartz. Shock stage
Main orientations
Additional orientations
Optical properties
1.Very weakly shocked
PFs: (0001)
PFs: rarely {10]1}
normal
2.Weakly shocked
PDFs: {10i3}
PFs: {10]1}, (0001) PDFs: rare
normal
3,Moderately shocked
PDFs: {10]3}
PFs: {10]1}, (0001) rare PDFs: {11~2}, {11~1},(0001), {1010} + {11~1}, {10~1}, {21~1}, {51~1}
normal or slightly reduced refractive indices
4. Strongly shocked
PDFs: {10~2} {10~3}
PFs: rare or absent PDFs: {11~2}, 111~1},(0001), {10~0} + {1151}, {10~1}, {21"31}, {5161}
reduced refractive indices 1.546-1.48
5.Very strongly shocked
PDFs: {10i2} {1013}
None
reduced refractive indices (<1.48)
PFs: planar fractures; PDFs: planar deformation features; after St6ffier and Langenhorst (1994).
The pre-shock temperature of a target rock also influences the formation and distribution of PDFs (Langenhorst et al. 1992). Reimold (1988), Huffman et al. (1993), and Huffman and Reimold (1996) presented the results of shock experiments with quartzite and granite at room temperature (25 °C), and preheated to 450 °C and 750 °C. They noticed a slight difference in the relative distribution of the {1013} and {1012} orientations and a large difference in the number of PDF sets per grain (Fig. 1.6.4.3). Langenhorst (1993) and Langenhorst and Deutsch (1994) compared PDF orientations in shocked quartz single crystals preheated to a higher temperature than Huffman et al. (1993) and found a distinct change in the relative frequencies of the {1013} and {1012} orientations.
33
0
I~ ~
I~
40
so
1000rains 163 sets/91grains
30
2oi 10
0'0'1"2'3"
.............. "~s e ~ =o 10(3grains
O~
b)
40
I
I
°1.~°, o~..
LL
30 20 10
o .
.
.
.
3'
sets per grain
0 0
;o
;o
Angle between c-Axis and Poles of PDFs
Fig. 1.6.4.3. Histogram with crystallographic orientation of PDFs in quartz from Hospital Hill quartzite from the Witwatersrand Basin, showing the dependency of the orientations on the preshock temperature (after Huffman et al. 1993). a) Pre-shock temperature 25 °C, shock pressure 28 GPa. b) Pre-shock temperature 440 °C, shock pressure 28 GPa. The main difference between the sets is that about half of the quartz grains in the high-temperature experiment remain unshocked, whereas in the low-temperature experiment, almost all quartz grains are shocked.
1.6.5 Bulk Optical and other Properties It has been shown that there is a decrease of the density of shocked quartz with increasing shock pressure (Langenhorst 1993; cf. St6ffler and Langenhorst 1994). At shock pressures up to about 25 GPa, only a slight decrease is noticeable, followed by a significant drop in density between 25 and 35 GPa, depending on the direction of the shock wave relative to the c-axis of the quartz crystal, and the preshock temperature. Optical properties, such as the birefringence of quartz and the refractive index, show also an inverse relationship with shock pressure in the 25 to 35 GPa range. At 35 GPa, isotropization (formation of diaplectic quartz glass) occurs. The data also indicate that with increasing shock pressure the birefringence (n~--n0 decreases. Still other properties of shocked minerals can be used to either confirm a shock history or calibrate shock pressures. For example, intensity and wavelength of infrared absorption bands, the electron paramagnetic resonance, and peak width in a 29Si magic angle spinning nuclear magnetic resonance
34
(NMR) spectrum all depend in a quantitative way on the shock pressure (e.g., Boslough et al. 1995; references in St6ffler and Langenhorst 1994).
1.6.6 Diaplectic Glass At shock pressures in excess of about 35 GPa, diaplectic glass is formed (Table 1.6.1.1), which has been found at numerous impact craters. It is an isotropic phase that preserves the crystal habit, original crystal defects, and, in some cases, planar features. It forms without melting by solid-state transformation and has been described as a phase "intermediate between crystalline and normal glassy phases" (St/Sffier and Hornemann 1972). For example, a phase called maskelynite forms from feldspar (Bunch et al. 1967). Diaplectic glass has a refractive index that is slightly lower, and a density that is slightly higher, than that of synthetic quartz glass. At pressures that exceed about 50 GPa, lechatelierite, a "normal" mineral melt, forms by fusion of quartz (see Sect. 1.6.8). Other minerals also undergo melting (fusion) at similar pressures. This complete melting is not the same process that results in the formation of diaplectic glass. The distinction between diaplectic glass and lechatelierite (both after quartz) was described by St6ffler and Hornemann (1972) and St6ffier and Langenhorst (1994).
1.6.7 High-Pressure Polymorphs A very important form of shock deformation are phase transitions to high-pressure polymorphs of minerals in a solid state transformation process. Such transformation can be predicted from Hugoniot data. Many minerals form metastable highpressure phases (St6ffler 1972). These include (density in g/cm 3 is given in parentheses): stishovite (4.23) and coesite (2.93) from quartz (2.65); jadeite (3.24) from plagioclase (2.63-2.76), majorite (3.67) from pyroxene (3.20-3.52); and ringwoodite (3.90) from olivine (3.22--4.34). In contrast to expectations from the equilibrium phase diagram of quartz, which can be used to predict phase transitions under static conditions, stishovite forms at lower shock pressures than coesite, probably because stishovite forms directly during shock compression, whereas coesite crystallizes during pressure release. The first time that coesite, the high-pressure modification of quartz, was detected in nature was at impact structures, and the presence of this phase has been taken as confirming evidence of an impact event (e.g., Chao et al. 1961). In addition, stishovite was for the first time discovered in nature at Meteor Crater, Arizona (Chao et al. 1962), and, to date, has only been observed in impact-deformed rocks. The formation probabilities and conditions for these phases are strongly dependent on the porosity of the target rocks. While stishovite has never been found in any natural non-impact related rocks, there are rare findings of coesite in metamorphic rocks of ultra-high pressure (UHP) origin or in kimberlites. However, coesite from UHP rocks can easily be distinguished from that in impact-
35
derived rocks. Coesite within UHP metamorphic rocks occurs as large single crystals within, or associated with, high-pressure minerals of metamorphic or volcanic origin, but never associated with quartz. On the other hand, impactderived coesite occurs as fine-grained, colorless to brownish, polycrystalline aggregates of up to 200 ktm in size, which are usually embedded in diaplectic quartz, or, rarely, in nearly isotropic shocked quartz or their recrystallization products. In addition to morphological differences, shock-produced coesite occurs in a disequilibrium assemblage of quartz-coesite-stishovite-glass (see also Grieve et al. 1996). Recently, a rare "post-stishovite" phase has been identified by Sharp et al. (1999), indicating very high shock pressures during its formation. In addition to high-pressure phases of rock-forming minerals, impact-derived diamonds (the high pressure modification of carbon) have also been found at various craters. These diamonds form from carbon in the target rocks, mainly in graphite-bearing (e.g., graphitic gneiss) or coal-bearing rocks (Koeberl et al. 1997a). Impact diamonds commonly preserve the crystal habit of their precursor material, which is mostly hexagonal graphite (some are coal-derived). For example, the gneissic target rocks at the Popigai impact structure in Siberia contain graphite flakes, crystals, and aggregates with sizes of 20 ~tm to about 10 mm. Well-shaped tabular graphite crystals are usually 0.1-1 mm in size and are elongated parallel to the gneissic fabric. Diamonds, which are also found in situ in shocked crystalline rocks, commonly show tabular shapes, indicating that they preserve the crystal habit of the precursor graphite crystals (Fig. 1.6.7.1). The diamonds that formed after graphite have been called "apographitic" diamonds.
~
ii~i~,~~, i
~!i
~
~i~
,~
~i¸
Fig. 1.6.7.1. Shock-produceddiamonds from the Popigai impact structure, Russia (grain size
about 0.5 mra) (photocourtesyV.I. Masaitis).
36
All impact diamonds are polycrystalline, with sizes of individual diamond microcrystals being on the order of 1 ~tm or less. Many of them were thought, from X-ray diffraction work, to contain up to several volume percent lonsdaleite, the rare hexagonal diamond modification. However, TEM investigations show that the diamonds have an internal layered texture with thicknesses of a few micrometers, which may be inherited from the precursor graphite. TEM also shows that locally the cubic diamond phase is intergrown with a lamellar phase or defect. The lamellae could either represent stacking faults or microtwins. If multiple stacking faults occur, the lamellae could be interpreted to be lonsdaleite, the hexagonal diamond polymorph. More recent TEM work also failed to identify the presence of lonsdaleite and rather seems to suggest that stacking faults in the diamond microcrystals mimic the X-ray pattern of the hexagonal phase (Koeberl et al. 1997a; Hough et al. 1998; Langenhorst et al. 1999). Impact-derived diamonds have also been found to be intergrown with silicon carbide (SIC) in suevites from the Ries crater in Germany (Hough et al. 1995), and at the K/T boundary (see Sect. 3.2.1). 1.6.8 Mineral and Rock Melts At pressures in excess of about 60 GPa, rocks undergo complete (bulk) melting to form impact melts (see Table 1.6.1.1). The melts can reach very high temperatures due to the passage of shock waves that generate temperatures far beyond those commonly encountered in normal crustal processes or in volcanic eruptions. The high temperatures are demonstrated by the presence of inclusions of hightemperature minerals, such as lechatelierite, which is the monomineralic quartz melt and forms from pure quartz at temperatures >1700 °C (see above), or baddeleyite, which is the thermal decomposition product of zircon, forming at a temperature of about 1900 °C. Lechatelierite is not found in any other natural rock, except in fulgurites, which form by fusion of soil or sand when lightning hits the ground. Lechatelierite does not occur in any volcanic igneous rocks. If higher temperatures persist, not only individual minerals undergo melting, but whole rocks and rock units can melt. Impact melts may also go through a phase of superheating (i.e., staying liquid even though the vaporization temperature has been exceeded) at temperatures of 10,000 °C or higher (e.g., Jakes et al. 1992; Melosh 1998). Depending on the initial temperature, the location within the crater, the composition of the melt, and the speed of cooling, impact melts either form impact glasses (if they cool fast enough), or, more commonly, (mostly) finegrained impact melt rocks (if they cool slower). Impact melt rocks are also found as inclusions in suevitic breccias in the form of glass fragments or melt clasts (Fig. 1.6.8.1, and see Sect. 1.7). Impact melt rocks contain clasts of shocked minerals or lithic clasts. Recently, carbonate melts have been identified at the Ries crater in Germany (Graup 1999). As glasses are metastable supercooled liquids, impact glasses slowly recrystallize (if dissolution is not acting faster), at a rate that depends on the composition of
37
the glass and post-impact environmental conditions. Therefore, impact glasses are more commonly found at young impact craters than at old impact structures. Very fine-grained recrystallization textures are often characteristic for devitrified impact glasses. Impact glasses have chemical and isotopic compositions that are very similar to those of individual target rocks or mixtures of several rock types. For example, it is possible to use the rare earth element (REE) distribution patterns, or the Rb-Sr isotopic composition, which are identical to those of the (often sedimentary or metasedimentary) target rocks, to distinguish the impact melt rocks from intrusive or volcanic rocks (e.g., Blum and Chamberlain 1992; Blum et al. 1993). Furthermore, impact glasses have much lower water contents (about 0.0010.05 wt.%) than volcanic or other natural glasses (e.g., Koeberl 1992b). Detailed descriptions of impact melts and glasses and their characteristics and compositions are discussed by, for example, E1 Goresy et al. (1968), Dence (1971), St6ffier (1984), Koeberl (1986, 1992a, b), Vishnevsky and Montanari (1999), and references therein. See also Sects. 2.4 and 2.5.
Fig. 1.6.8.1. Aphanitic impact melt breccia from suevite deposits on the north side of the Bosumtwi crater, Ghana. A small quartz clast near the center of the image shows ballen structure. Width of image 3.4 ram, parallel polars (photo courtesy W.U. Reimold).
38
Impact melt rocks are true igneous rocks that have formed by cooling and crystallization of high-temperature silicate melts. They often have textures and mineral compositions that are similar to those of volcanic igneous rocks, which may make it difficult to judge the impact origin from an isolated sample. Field evidence should be used to determine if large-scale melt rock volumes are associated with other, more distinctive, shocked rocks (that did not undergo complete melting). Occasionally, in individual samples, evidence for an impact origin can be obtained from careful petrographic and geochemical studies. Impact melt rocks often preserve inclusions of not completely melted rock and mineral fragments that may show evidence for shock metamorphism in the form of PDFs in rockforming minerals. The presence of lechatelierite may be characteristic, as well as the so-called "Ballen" texture, where lechatelierite forms a distinctive "crackled" pattern of curved fractures that may result from (partial) devitrification of the quartz melt (see Carstens 1975 and French 1998, pp 94-95). Chemical studies may also provide evidence for an impact origin of a melt rock. For example, Sr isotope analyses are able to distinguish between the composition of volcanic rocks and that of locally melted crustal rocks. The presence of a meteoritic component in such rocks also provides clear evidence of an impact origin (see Sect. 1.8). Impact melts and glasses (or minerals that have recrystallized from the melt; e.g., Krogh et al. 1993a, b; Izett et al. 1994) have another important use, as they often are the most suitable material for the dating of an impact structure (see Sect. 1.9).
Fig. 1.6.8.2. Ballen structure in quartz from loose suevitic gravel of the Saltpan (Tswaing) impact crater, South Africa. Width of image 1.1 mm, parallel polarizers (photo courtesy W.U. Reimold).
39
1.7 Classification of Impactites At this point a short review of the nomenclature of impactites might be useful, as different terminologies for the rock types at a crater have been used by various authors. In general, it is best to follow well-established and widely accepted classification criteria of impactites discussed by, e.g., St6ffler et al. (1979), St6ffler and Grieve (1994a, b), and French (1998). In some aspects crater-specific terminologies might have some advantages, because they refer to the local rock types; on the other hand, local terms make it very difficult to compare rock units from different impact structures. A possible shortcoming of the general impactite terminology may be the lack of genetic information, for example, with regard to the possibility that more than one type of suevitic or fragmental impact breccia may have been deposited, perhaps by different processes, such as atmospheric fall-out, or base surge deposition, within the crater (e.g., Vishnevsky and Montanari 1999). Following St6ffler and Grieve (1994b) and French (1998), the following terms and definitions of common impact formations can be used. An impactite is a collective term for all rocks affected by (an) impact(s) resulting from collision(s) of planetary bodies. Their classification scheme (for single impacts) uses two sets of criteria for a) a combination of lithological components, texture, and degree of shock metamorphism, and b) mode of occurrence (in- or outside the crater). In terms of location, a fundamental distinction is made between parautochthonous rocks beneath and allochthonous (or allogenic) rocks that fill the crater (crater-fill units, e.g., breccias and melt rocks) and also occur as ejecta around the crater. French (1998) distinguishes four locations in and around an impact structure, which are, with their associated rock units: a) sub-crater (parautochthonous rocks, cross-cutting allogenic units, pseudotachylite); b) crater interior (allogenic craterfill deposits: lithic [fragmental] breccias, suevitic breccias, impact melt breccias); c) crater rim region (proximal ejecta deposits), and d) distal ejecta (for a discussion of the latter, see Sect. 2.1). Parautochthonous rocks may include target rocks that were subjected to shock metamorphism but remained in place, as well as impactites (e.g., monomict fragmental impact breccia that remained in situ, but was internally brecciated, and where breccia clasts were subjected to small-scale movements or rotation). Another breccia type, pseudotachylite, has been reported from sub-crater basement, in the form of small veins and dikes hardly ever exceeding a few centimeters width. Only in the large Sudbury and Vredefort structures have abundant volumes of such breccia been observed. As pseudotachylite in general usage is a term reserved for friction melt rock - not only in impact but also in tectonic settings - and because in impact crater floors a whole range of different dike breccias (including impact melt breccia, fragmental, and suevitic breccia injections, or clastic breccias, such as cataclasites, or even pre- or post-impact tectonically produced pseudotachylites) may occur, it has been recommended (Reimold 1995, 1998) to use the term pseudotachylite with caution. All the breccia types mentioned may
40
macroscopically appear like true pseudotachylite, and diligent micro-analysis is required to resolve the true nature of these breccias in question. Particularly, it should be reserved for occurrences of true friction melts only. Instead, the term "pseudotachylitic breccia" could be used as a field term and in such instances where the true nature of such material has not been confirmed (yet). It has been suggested that some pseudotachylites formed during late-stage crater developments and modification (e.g., Spray 1995, 1997; Spray and Thompson 1995). The crater fill contains a variety of breccia types. Fragmental impact breccia is a "monomict or polymict impact breccia with clastic matrix containing shocked and unshocked mineral and lithic clasts, but lacking cogenetic impact melt particles" (St6ffier and Grieve 1994b). This type has also been called a lithic breccia (French 1998). Impact melt breccia is also a common type, which is defined by St6ffier and Grieve (1994b) as an "impact melt rock containing lithic and mineral clasts displaying variable degrees of shock metamorphism in a crystalline, semihyaline or hyaline matrix (crystalline or glassy impact melt breccias)" (with an impact melt rock being a "crystalline, semihyaline or hyaline rock solidified from impact melt"). Suevite (or suevitic breccia; Figs. 1.7.1-1.7.3) is defined as a "polymict breccia with clastic matrix containing lithic and mineral clasts in various stages of shock metamorphism including cogenetic impact melt particles which are in a glassy or crystallized state". The distribution of the rock types is a function of their formation and the order in which they formed. For example, lithic breccias can occur not only inside, but also outside a crater. At the Ries crater in Germany, a distinctively colored polymict lithic breccia, the so-called "Bunte Breccia", occurs beneath melt-bearing suevites both inside and outside the crater, with a sharp contact between the two units (see, e.g., H6rz et al. 1983). For the identification of meteorite impact structures, suevites and impact melt breccias (or impact melt rocks) are the most commonly studied units. Despite the detailed definition given above, an easy way to distinguish between the two types is the following: suevites are polymict breccias that contain inclusions of melt rock (or impact glass), i.e., they are clast-dominated ("melt fragment breccias"), and impact melt breccias have a melt matrix with a variable amount of (often shocked) rock fragment inclusions (they are matrix-dominated breccias that also have been termed "melt-matrix breccias"). The rocks in the crater rim zone are usually only subjected to relatively low shock pressures (commonly <2 GPa), leading mostly to fracturing and brecciation, and often do not show shock-characteristic deformation. Thus, even at larger craters in situ crater rim rocks rarely show evidence for shock deformation (Reimold et al. 1998a; Koeberl et al. 1998a). The best indication for impact in these locations is the occurrence of shocked ejecta, such as suevites and melt rocks (or impact glasses), or the presence of so-called dike breccias (e.g., Lambert 1981). In wellpreserved impact structures the area immediately outside the crater rim is covered by a sequence of different impactite deposits (see, e.g., H6rz et al. 1983; French 1998), which often allow the identification of these structures as being of impact origin.
41
Fig. 1.7.1. Large blocks of suevitic breccia are found within less than one crater radius outside the rim of the Bosumtwi crater, Ghana (with one of the authors, C.K.).
Fig. 1.7.2. Cut slab of suevitic breccia from the Bosumtwi crater, Ghana, showing the variety of clasts within the fine-grained matrix. Dark frothy areas are glass.
42
Distal impact deposits are difficult to describe in any standard nomenclature prompting a suggestion of the use of stratigraphic terminology by King and Petruny (1999).
Fig. 1.7.3. High-resolution X-ray computed tomography image of a 5-cm-sized suevite from the Bosumtwi crater, Ghana. The matrix has been removed by computer processing, showing the clast population (different clast densities are indicated by variations in brightness). From a study by Koeberl et al., in preparation (see also Koeberl et al. 1998c).
1.8 Meteoritic Components in Impactites The verification of an extraterrestrial component in impact-derived melt rocks or breccias can be of diagnostic value to provide confirming evidence for an impact origin of a geological structure. Geochemical methods are used to determine the presence of the traces of such a component. The presence of actual meteorite fragments at a crater structure is rare. This is a consequence of the physics of an impact event. A shock wave, similar to the one that penetrates through the target, also passes through the meteoritic impactor and, within fractions of a second, vaporizes most, or all, of the projectile. Only during the impact of small objects (less than about 40 m in diameter, depending on impact angle and velocity), because of spallation during entry into the atmosphere or due to lower impact velocity resulting from atmospheric drag, a small fraction of the initial mass of the
43
meteorite may survive. The cut-off diameter of impact craters at which some fraction of meteoritic material may be preserved is about 1-1.5 km. A good example is Meteor Crater, Arizona, where only about 2% of the estimated total mass of the iron meteorite impactor have been found around the crater. In addition, a large number of small iron-rich spheroids were found around the crater, which did undergo melting during the cratering event; these amount to about 5% of the original impactor mass. Recent theoretical modeling calculations, as well as 59Ni isotopic measurements on the spherules and meteorites show that most of the projectile had melted and only little was vaporized, and that a part of the outer shell of the projectile (amounting to a maximum of 16% of its mass; see Schnabel et al. 1999) remained solid on the rear surface. Thus, even under optimistic conditions, meteoritic fragments are only preserved at very young and small craters. The absence of meteorite fragments can, therefore, not be used as evidence against an impact origin of a crater structure. In the absence of actual meteorite fragments, it is necessary to search for traces of meteoritic material that is mixed in with the target rocks in breccias and melt rocks. This can be done by studying the concentrations and interelement ratios of siderophile elements, especially the platinum group elements, which are several orders of magnitude more abundant in meteorites than in terrestrial upper crustal rocks. The usage of platinum group element abundances and ratios avoids some of the ambiguities that may result if only common siderophile elements (e.g., Cr, Co, Ni) are considered. However, problems may arise if the target rocks have high abundances of siderophile elements, or if the siderophile element concentrations in the impactites are very low. In such cases, the Re-Os isotopic system (Sect. 1.8.3) and the Cr isotope system (Sect. 1.8.4) have recently been used for establishing the presence of a meteoritic component in a number of impact melt rocks and breccias. Meteoritic components have been identified for about 41 impact structures (out of more than 160 known on Earth; see Koeberl 1998 for a listing), which reflects also the detail in which these structures were studied. The following discussion follows mostly the review by Koeberl (1998).
1.8.1 Meteoritic Components and Siderophile Element Analyses During impact, a small amount of the finely dispersed meteoritic melt (droplets) or vapor is mixed in with a much larger quantity of target rock vapor and melt, which later forms impact melt rocks, melt breccias, or glass. In most cases, the contribution of meteoritic matter to these impactite lithologies is very small (commonly <<1% by weight), leading to only slight chemical changes in the resulting impactites. The detection of such small amounts of meteoritic matter within the normal upper crustal compositional signature of the target rocks is extremely difficult. Only elements that have high abundances in meteorites, but low abundances in terrestrial crustal rocks, such as the siderophile elements, can be used to detect such a meteoritic component. Another complication is the existence of a variety of meteorite groups and types (the three main groups are stony meteorites, iron me-
44
teorites, and stony-iron meteorites, in order of decreasing abundance), which have widely varying siderophile element compositions. Distinctly higher siderophile element contents in impact melts, compared to target rock abundances, can be indicative of the presence of either a chondritic or an iron meteoritic component. Achondritic projectiles are much more difficult to discern, because they have significantly lower abundances of the key siderophile elements. Siderophile (and related) elements that have often been used are Ni, Co, Cr. In addition, the interelement ratios of these elements are an effective discriminator. If the meteoritic contribution is exceeding 0.1%, it is possible to distinguish between stony meteorites (chondrites) and iron meteorites, because chondrites have high abundances of Cr (typically about 0.26 wt.%), whereas iron meteorites have Cr abundances that are much more variable, but typically about 100 times lower than those of chondrites, and low Ni/Cr or Co/Cr ratios. For this reason, several authors (e.g., Palme et al. 1978; Evans et al. 1993) have used the Cr abundance, together with the Ni/Cr or Co/Cr ratios in impact melts, to distinguish between iron and chondritic projectiles. Unfortunately, the abundances of Co, Cr, and Ni are not particularly low in most terrestrial rocks. Thus, there may be a relatively high (and variable) indigenous component that is derived from the target rocks. If any conclusions are to be drawn from the abundances of elements such as Cr, Ni, and Co, a detailed study of their abundances in the target rocks needs to be done (cf. Palme 1980). From mixing calculations it is possible to determine the relative proportions of the various target rocks types that are contributing to breccias or melt rocks. Thus, a bulk composition of a breccia (or melt rock) can be modeled, and the siderophile element composition of this model calculation compared with the actually observed siderophile element abundances in the impactites. The first studies on meteoritic components were done not on terrestrial impactites, but on lunar rocks. These have shown that the platinum group elements (PGEs: Ru, Rh, Pd, Os, Ir, Pt) and Au are better suited for identifying a meteoritic component than Cr, Co, and Ni (e.g., Morgan et al. 1975; Palme et al. 1978, 1979; Evans et al. 1993; Schmidt and Pernicka 1994). The abundances of the PGEs in chondrites and most iron meteorites are several orders of magnitude higher than those in terrestrial crustal rocks, as illustrated for Ir in Fig. 1.8.1.1. The range of Ir and Os abundances in chondrites is about 400 to 800 ppb, while iron meteorites show a much wider range. In contrast, continental crustal rocks contain on the order of 0.02 ppb Ir or Os (e.g., Taylor and McLennan 1985). Thus, the signal to background ratio is very high for the PGEs (i.e., low indigenous concentrations; high concentrations in the "contaminating" meteorite). The admixture of minor quantities of meteoritic material (chondrite, iron meteorite) to crustal target rocks yields significantly elevated abundances of the PGEs in the resulting impact melt rocks or breccias. For example, if only 1 wt.% of a chondritic meteorite is mixed into terrestrial crustal target rocks, the resulting breccia or melt will contain about 4 ppb of It. Even 0.1 wt.% of a chondritic component still results in 0.4 ppb of Ir (or Os) in the breccia, which is at least one order of magnitude higher than average crustal background values. Achondrites have a much wider range of Ir and Os contents, and, in general, lower abundances
45
than for chondrites (e.g., Morgan et al. 1979; Schmidt and Pemicka 1994). Iron meteorites (Buchwald 1975) show widely varying PGE abundances, depending on the meteorite type. Using siderophile element abundances and interelement ratios, the projectile type was determined for a number of terrestrial craters.
10 Chondritic Meteorites (ca. 300 - 1000 ppb)
..Q El. O_
Upper Mantle
V
c-
Tektites
K/T Boundary Clay
Ocean
0 I-i
0.1
Continental Crust
Floor Basalts Impact Melt Rocks
0.01
Fig. 1.8.1.1. Range of Ir contents in typical terrestrial and extraterrestrial rocks (diagram after Koeberl 1998).
As a general rule, the larger the crater, the more likely it is that the projectile has been melted or vaporized, although the impact angle also plays an important role (e.g., Pierazzo and Melosh 2000). Most small impact craters (those with less than about 1.5 km diameter) were formed by iron projectiles of known composi-
46
tion (because meteorite fragments were recovered, e.g., at Wolf Creek or Meteor Crater), with the exception of the Saltpan (Tswaing) crater (South Africa), which was formed by the impact of a chondritic body (see Koeberl et al. 1994a). Some of the smaller structures are in fact crater fields consisting of several more or less circular structures, such as Wabar, Henbury, and Odessa (at all of which iron meteorite fragments have been recovered). All craters that are associated with meteorite fragments are relatively young (less than about 0.1 Ma), whereas at older craters (e.g., the 3.1 Ma Aouelloul crater, Mauritania) no remnants of the actual impactor were recovered. While the Saltpan crater is only 0.22 Ma old, no remnants of the impacting chondrite were found (most likely do to erosion of any remaining fragments). An unusual case is the Rio Cuarto crater field in Argentina, because it consists of at least ten rimmed, oblong structures ranging in size between about 0.1 x 0.3 and 4.5 x 1.1 km, which formed by a very low angle (grazing) impact of a chondritic body, with the top of the impactor being decapitated and producing the down-range crater structures (e.g., Schultz et al. 1994). In contrast to the Saltpan crater, a small mass of the chondritic impactor (of H4/5 type) that formed the much larger Rio Cuarto crater field is still preserved. This could be due to the young age of the structure (probably as low as 2000 to 4000 years, based on preliminary fission track ages), and because of the oblique impact (and resulting impactor decapitation), which helped to preserve parts of the projectile. In most impact structures, impact melt rocks (or breccias) are often the only material in which a meteoritic component can be found. The results of studies using PGE and other siderophile element distributions indicated that in almost all cases the amount of the extraterrestrial component in such impact-derived rocks is less than 1% (e.g., Morgan et al. 1975; Palme et al. 1978, 1979; G6bel et al. 1980; Koeberl et al. 1994a; French et al. 1997; see also Koeberl 1998). Only in a few cases are higher amounts found, such as at East Clearwater (Canada), where some but not all - impact melt rock samples contain up to 10% of a meteoritic component (Palme et al. 1981), or at Morokweng (South Africa) with up to about 4% of a chondritic component (Koeberl et al. 1997c). In a number of studies of PGE abundances and interelement ratios, it was attempted to use these values to determine the type or class of meteorite for the impactor (e.g., Morgan et al. 1975; Palme et al. 1978, 1979; Evans et al. 1993), but these attempts were not always successful. Suggestions regarding a distinction between asteroidal and cometary sources are relatively useless because so far no unambiguously cometary material has ever been retrieved and analyzed for its trace element composition. Not only is it difficult to decide between chondrite types, but it should also be pointed out that conflicting identifications have been made for a number of impact structures. Many type identifications are highly uncertain. For example, both iron and chondritic projectiles were proposed for the Bosumtwi (Ghana), Zhamanshin (Kazakhstan), and Rochechouart (France) impact structures (see Koeberl 1998 for details). Clearly, the identification of a meteoritic component in impactites is not a trivial problem. -
47
1.8.2 Problems with Meteoritic Component Identification Apart from the seemingly straightforward cases in which meteorite fragments are found at a crater, inferences about the projectile type have to be made from the abundances and interelement ratios of various siderophile elements in impactites. However, several complications are introduced by complex fractionation processes that seem to take place during the formation of impact glasses and melts. In recent studies of impact glasses from some small craters for which the meteorite has been partly preserved (e.g., Meteor Crater, Wabar, and some Australian craters), it was found that the siderophile elements show strong (and highly variable!) fractionation in the interelement ratios compared to the initial ratios in the impacting meteorite. The changes do not seem to be correlated in a straightforward way with any physical or chemical properties of the elements (Hrrz et al. 1989; Attrep et al. 1991a, Mittlefehldt et al. 1992a, b). Mittlefehldt et al. (1992b) argued against simple vapor fractionation of the chemical elements as well as post-depositional fractionation. Instead, they proposed that the siderophile elements may have been fractionated from each other during the early phases of the impact, while the projectile was undergoing decompression and before mixing with the target materials, although they were unable to explain the fractionation with a specific model. In general, though, there is a correlation between the amount of melt and vapor with increasing impact velocity (e.g., Pierazzo et al. 1997), which may, thus, be the most important factor controlling the incorporation of a meteoritic component (the amount of which is known to vary widely between craters of similar size, and also within impact breccias and melt rocks from a single crater). However, this energy scaling relationship would not explain the fractionation within a single crater. This observation does not bode well for any attempts to directly infer projectile types of small craters from siderophile element ratios in impactites. And, indeed, the element ratios at, for example, Aouelloul or Brent do not readily conform to those of any known meteorite types, but can be interpreted in various ways. To allow the identification of a meteoritic component in impactites, the abundances of PGEs and other siderophile elements in the impactites have to be compared with those in the target rocks. Ideally, these indigenous concentrations should be determined and subtracted from the abundances found in the impact melt rocks, and yield the "pure" meteoritic abundance ratios (e.g., Morgan and Wandless 1983). Thus, it is necessary to analyze all rock types that are known or suspected to be present in the pre-impact target area (in some cases, clasts within breccias can be used). Mixing calculations (see, e.g., French et al. 1997) can be used to establish the relative proportions of the target rocks types that were mixed to form impact melt rocks or breccias, which then allows to subtract a proper indigenous component from the melt or breccia composition. This procedure may yield good results only if the target stratigraphy is simple (i.e., not involving too many rock types, which should also be distinct in composition). In reality, though,
48
the exact target rocks that were involved in forming impact melt rocks or breccia are not always well known (e.g., due to later erosion of the target stratigraphy), or because of very low or highly variable indigenous PGE concentrations (see, e.g., Schmidt and Pernicka 1994; Pernicka et al. 1996). Palme (1982) used the Au/Ir ratio to distinguish between cosmic and terrestrial signatures. However, Au is much more mobile than Ir under a number of terrestrial conditions (e.g., weathering, diagenesis, metamorphism), which may lead to non-chondritic Ir/Au ratios even if a meteoritic component is present in impactderived rocks. Specifically, Au often shows high indigenous abundances in some terrestrial rocks, yielding low (non-chondritic) Ir/Au ratios. Additional complications arise because PGEs are enriched in some rock types (e.g., mafic and ultramafic rocks and mineralized rocks). The PGE patterns of the mantle and in some mantle-derived rocks may be similar to those of chondrites, and the PGE abundances in mantle rocks are also higher than those in the crust by factors of about 10 2 to 10 3, making a distinction between an exposed mantle section or a component in the impactites derived from a mafic to ultramafic precursor rock and a meteoritic component quite difficult, if not impossible. Siderophile element fractionation may also occur in the impact melt while it is still molten. This effect may be significant in larger craters, because there the melt could stay hot for many thousand years. Different mineral phases, such as sulfides or oxides (e.g., magnetite, chromite), may take up various proportions of the PGEs or other siderophile elements, leading to an irregular distribution of these elements and possibly fractionated interelement ratios and patterns. Such irregular distribution of siderophiles is known from, for example, the East and West Clearwater impact structures (Palme et al. 1979), or the Chicxulub impact structure (Koeberl et al. 1994c; see also below). Hydrothermal processes associated with the hot impact melt may also change PGE abundances. In contrast to a widely held opinion, actual data show that meteoritic components are often inhomogeneously distributed in impact melt rocks and breccias (e.g., data in Palme et al. 1979; Koeberl et al. 1994a-c; Schuraytz et al. 1994). A variety of fractionation effects have also been documented for distal ejecta from the K/T boundary impact at various localities around the world (e.g., Evans et al. 1993). For example, high PGE abundances were discovered in impact ejecta from the Acraman structure in Australia (see Sect. 3.4), but show deviations from chondritic patterns due to low-temperature hydrothermal alteration (e.g., Gostin et al. 1989; Wallace et al. 1990b; cf. also Colodner et al. 1992). The limitations and complications discussed above make the proper identification of a meteoritic component difficult. The determination of a specific projectile type is even more difficult and can yield ambiguous results. Thus, the use of some more sensitive and selective methods for meteoritic component detection and identification would be desirable.
49
1.8.3 Osmium Isotopes in Impact Studies The Os isotopic system is such a more sensitive method and has some advantages over the use of PGE elemental abundances. The method is superior with respect to detection limit and selectivity, as discussed by Koeberl and Shirey (1993, 1997) and Koeberl et al. (1994a-c). In principle, the abundances of Re and Os and the '88Os/'87Os isotopic ratios, which are measured by very sensitive mass spectrometric techniques, allow to distinguish the isotopic signatures of meteoritic and terrestrial Os; this was for the first time shown by Fehn et al. (1986), whose technique, however, lacked the sensitivity of modern analytical methods. Meteorites (and the terrestrial mantle) have much higher (by factors of 102-105) PGE contents than terrestrial crustal rocks. In addition, meteorites have relatively low Re and high Os abundances, resulting in Re/Os ratios less or equal to 0.1, while the Re/Os ratio of terrestrial crustal rocks is usually no less than 10. More importantly even, the ~88Os/187Os isotopic ratios for meteorites and terrestrial crustal rocks are significantly different. 187Os is formed from the B-decay of ~87Re (with a half-life of 42.3+1.3 Ga). Thus, due to the high Re and low Os concentrations in old crustal rocks, their '87Os/188Os ratio increases rapidly with time. The present day '8~Os/~88Osratio of mantle rocks is about 0.13. Meteorites also have low 187Os/188Osratios of about 0.11 to 0.18. Osmium is much more abundant in meteorites than Re, leading to only small changes in the meteoritic l"7Os/~S"Osratio with time. Because of the high Os abundances in meteorites, the addition of a minute meteoritical contribution to the crustal target rocks leads to an almost complete change of the Os isotopic signature of the resulting impact melt or breccia (see Fig. 1.8.3.1 for an example). The Os isotopic method does not, however, allow the determination of the projectile type. It is necessary, however, to distinguish between a possible mantle signal and an extraterrestrial signal, as the Os isotopic ratios for mantle and meteoritic material are very similar. Fortunately, however, there is a significant difference in the total abundance of Os between mantle rocks (which have about 1-4 ppb Os) and meteorites (typical chondrites have about 400-800 ppb Os). Thus, about 100 times more mantle material than meteoritic material would need to be added to normal crustal rocks (e.g., in a breccia) to result in the same Os isotopic ratio of the bulk rock. A detailed geological field investigation, and a petrographic study of the rocks in question, if necessary combined with trace element and Rb-Sr and/or Sm-Nd isotopic analyses, will easily show if significant amounts of ultramafic materials are present. For details about this method, see Koeberl and Shirey (1993, 1996, 1997). Case studies for a variety of impact structures are presented by (e.g.) Walker et al. (1991), Dickin et al. (1992), Koeberl et al. (1994a-c, 1996d, 1998a) and French et al. (1997). For the use of the method in investigations of the K/T boundary, see Sect. 3.2.1. Similar to studies of shock metamorphism, Os isotopic measurements of target rocks and impactites may be used as evidence in favor of an impact origin of a new or doubtful structure.
50
1.0 0.8
t Rocks
m
¢/}
O
oo co
0.6
¢/}
O oO
0.4
Impact Breccias
0.2 -
.._.___
I
0.0
0
I
Meteorites
I
I
I
I
I
I ...... I
5
I
I
I
10
I............ I
l
15
l
l
1
I
2O
187Re/1880s
Fig. 1.8.3.1. Ratios of ~87Os/~88Osversus ~87Re/188Osfor target rocks (shale and sandstone) of the Kalkkop impact crater, South Africa (see Reimo]d et al. 1998b), in comparison with data for four impact breccias (solid triangles) and the data array for chondritic and iron meteorites (small solid dots). The sample depths in the drill core are given as well (after Koeberl et al. 1994b). The dotted area marks the mixing field between target rocks and meteorites. All impact breccias fall within this mixing field; breccia-3 plots very close to the meteorite data mxay, indicating that this sample contains a larger meteoritic contributions than analyzed for any other breccia sample, which is in good agreement with the high Os content of this sample (about 0.2 ppb). In addition to distinct differences in the Os isotopic composition, the Os content of the target rocks, at about 0.02 ppb, is ca. 10 times lower than the Os content of the breccias.
1.8.4 Chromium Isotope Systematics Recently, the usage of another isotopic system has been explored for impact studies, It has been shown that the isotopic composition of the element chromium, in terms of the isotopes ~2Cr and 53Cr, differs between individual meteorite groups
51
(e.g., Shukolyukov and Lugmair 1998). For example, ordinary chondrites (types H and L) have isotopic characteristics that are slightly different from those of enstatite chondrites and are, even more significantly, different from those of carbonaceous chondrites. In contrast, all terrestrial materials analyzed so far (see Shukolyukov and Lugmair 1998) show no or only insignificant variation and are indistinguishable from the zero value 53Cr/52Cr- t0. Thus, assuming that a certain (fairly significant) percentage of the chromium in an impact melt or ejecta layer is of extraterrestrial origin, it should be possible by measuring the Cr isotopic composition to determine not only that an extraterrestrial component is present, but also which meteorite type might have been involved. Shukolyukov and Lugmair (1998) used this method to determine a carbonaceous chondritic component at the K/T boundary and Shukolyukov et al. (1999) showed that the meteoritic component in impact melt from the Morokweng impact structure in South Africa (see Sect. 3.5) is of ordinary chondritic affinity. However, this powerful and potentially very selective method is not without problems either. The differences in isotopic composition are very small, requiring extremely precise and time-consuming measurements, which severely limit the number of samples that can be measured and, therefore, invalidate the use of this technique as a screening tool for structures of unknown origin. This is far from a routine method that is only done in very few laboratories. Furthermore, a substantial amount of the chromium has to be of extraterrestrial origin to show an effect in the Cr isotopic composition that is larger than the precision of the measurement. Thus, while being more selective than the Os isotopic method, the Cr isotopic method is much less sensitive. Once again it becomes clear that no silver bullet exists in impact geochemistry.
1.9 Dating of Impact Structures Of the about 160 impact structures known today, precise ages have been determined only for a small fraction. In principle, it should be possible to precisely date impact craters, as they mark geologically instantaneous events. Precise ages (with a precision better than 1 or 2 rel.%) are necessary to a) understand the frequency with which impact events of a given size occur, b) to compare this value with astronomical considerations for impact frequency, c) to link impact craters and distal ejecta horizons, d) to compare the ages of large impact structures with those of mass extinction horizons in the geological record, and e) to test the hypothesis that impacts occur with a certain periodicity. Some of these relationships require the comparison of radiometric age determination techniques and biostratigraphic methods. The methods most commonly used for dating of impact melt rocks or glasses include the K-Ar, 4°Ar-39Ar, fission track, Rb-Sr, Sm-Nd, or U - T h - P b isotope methods, However, dating of impact craters is complicated and tedious and, if not done with utmost care, can easily lead to erroneous results. Bottomley
52
et al. (1990), and, especially, Deutsch and Sch~er (1994) provided excellent and detailed reviews of impact crater dating; thus, a short summary will be given here. There are two different approaches to the dating of impact structures. The first approach uses impact-derived rocks directly in or around the crater, usually for radiometric dating of melt rocks, and the second approach uses (distal) impact ejecta and tries to obtain a date for them based on (bio)stratigraphic data, and then uses this age to date an associated crater. First, we will discuss some aspects and methods used in dating crater rocks (breccias, melt rocks). A wide variety of geochronological methods has been used for the dating of impact craters, as their ages span the whole geological history of the Earth. The oldest currently known impact structure is Vredefort in South Africa at 2.023 Ga (e.g., Reimold and Gibson 1996), and the youngest craters formed only within the last few thousand years (e.g., Wabar in Saudi Arabia is only about 6000 years old; Storzer and Wagner 1977). This text cannot provide descriptions of the background of each dating method. The reader has to be referred to a standard textbook that includes geochronological methods (e.g., Faure 1986). Thus, we assume that the reader is familiar with the basics and methodology of these techniques. A very useful method in impactite dating is fission track dating. Most glassy materials, both within a crater and in distal ejecta (e.g., tektites, see Sect. 2.4.1), can be dated by counting fossil tracks and then comparing the number of fossil tracks with the number of tracks induced by irradiation in a reactor (for the determination of the uranium content). It is also possible to measure tracks in shocked minerals, such as apatite or zircon. Track fading and annealing may cause systematic errors that can be corrected by extensive experimental work (see, e.g., Storzer and Wagner 1982 for a review). Direct dating of impactites is often difficult due to inhomogeneity of the rocks, alteration, and limitations of the methods. For many methods it will be necessary to extract mineral separates and perform separate isotopic analyses. For example, the Rb-Sr isochron method (see Faure 1986) requires separation of several mineral phases, such as biotite, K-feldspar, and plagioclase to obtain the spread in isotopic ratios and elemental abundances that is necessary to define an isochron. If all minerals grew in the impact melt rock upon recrystallization, use of the isochron method will yield the age of the impact event. Problems can arise from postimpact hydrothermal or metamorphic processes and from devitrification of glassy or melt rocks. Another method involves U - T h - P b dating of zircons that have either been reset by the impact event (e.g., Kamo and Krogh 1995; Krogh et al. 1993a, b) or have grown in the hot melt (e.g., Kamo et al. 1996; Koeberl et al. 1997c). The small size of the zircons makes it necessary to use high precision methods (e.g., single zircon dating after air abrasion; Krogh et al. 1993a, b) or ion beam methods with high spatial resolution (Koeberl et al. 1997c). A common and precise method is the A r - A r technique, which uses the same decay system as the K - A r method (see Faure 1986), but allows the use of very small sample sizes and also to perform the K abundance determination and the Ar isotopic measurement in the same sample. Glassy or mineral fragments need to be isolated from the impactites for dating. After irradiation the sample chips are
53
heated either in an oven (stepwise heating) or with a laser to release the Ar, from which the age can then be calculated. Details of the use of this method for impact crater dating are given by Bottomley et al. (1990). Sample selection is also a crucial step - different samples from the same crater may give a variety of different results (e.g., Koeberl et al. 1990). While this is a potentially very precise method, it is still possible that some post-impact regional event reset the Ar isotopic system and ages obtained by this method, while still precise, do not date the actual impact event. An example is provided by the Gardnos crater in Norway, for which an age of about 550 to 600 Ma is preferred based on stratigraphic relationships, but AfAr dating of several samples gave a consistent age of 385 e 5 Ma (Grief et al. 1999). Clearly, abandoning local stratigraphic results in favor of an Ar-Ar age is an unpopular option. Distal impact ejecta are often discovered accidentally and their ages are determined from biostratigraphic relationships and paleomagnetic considerations. Such ejecta layers (in the impactite terminology they are called impactoclastic layers) may subsequently lead to the discovery of a source crater. For example, the impact ejecta layer at the K/T boundary led to the discovery of the Chicxulub structure, and the findings of impact ejecta in Australia led to the discovery of the Acraman structure (e.g., Gostin et al. 1986; Wallace et al. 1990a, b). These topics, and the relationship between impact ejecta and geological boundaries, will be discussed in detail in Chap. 3. The reverse problem, namely to search for the ejecta of a specific and known impact structure in a well-preserved stratigraphic sequence (e.g., at the Umbria-Marche sequence), is much more difficult, because of the lack of precise radiometric ages for many of the rock units involved, and because of correlation problems between radiometric and biostratigraphic (and paleomagnetic) age determinations. This question is discussed in detail for all of the geological boundaries and possible impact events recorded in the Umbria-Marche sequence in Chaps. 4 and 5. Table 1.9.1 lists the ages of impact structures that coincide with the stratigraphic record that is preserved in the Umbria-Marche sequence. Impact crater ages are important to determine the frequency of such events, and to discuss any possible periodicities in the crater record. Following the intriguing suggestion that the mass extinctions in the geological history are not randomly distributed in time, but follow a certain periodicity (Ranp and Sepkoski 1984; Sepkoski 1990, 1992, 1996), Alvarez and Muller (1984) proposed that the age of impact structures on Earth record a similar periodicity on the order of 26 to 30 million years. However, their analysis was based on an insufficient number of craters (some of which were imprecisely dated), and subsequent, statistically more extensive, studies by Grieve et al. (1985, 1988) failed to detect any periodicity. Thus, at present this hypothesis cannot be confirmed, mainly because of the insufficient number of (large) impact structures that have been dated with the necessary precision, and because most well-dated craters would only cover the past two or three cycles of an about 30 million years periodicity. It is hoped that in the future a major emphasis of crater studies will be to obtain precise dates for a large number of impact structures.
54
Table 1.9.1. List of impact structures on Earth younger than 250 Ma and larger than 5 km in diameter. Structure name and country
Diameter Age (km) (Ma)
Error (Ma)
Dating method
Reference
1 Bosumtwi (Ghana)
10.5
1.07
0.05
4°ArPgAr
Koeberl et al. 1997b
2 Zhamanshin (Kazakhstan)
13.5
1.09
0.05
fission track
Koeberl and Storzer 1988
3 Kara-Kui (Tajikistan)
52
2.5
2.5
stratigraphic?
Grieve et al. 1995
4 El'gygytgyn (Russia)
18
3.5
0.5
K/Ar
Gurov and Gurova 1980
5 Karla (Russia)
12
5
1
stratigraphic
Masaitis 1999
6 Bigach (Kazakhstan)
7
5
3
stratigraphic
Kilesev and Korotushenko 1986; Masaitis 1999
7 Ries (Germany)
24
15.1
1.0
4°Ar/3~Ar
Staudacher et al. 1982
8 Haughton (Canada)
24
23.4
1.0
4°Ar/39Ar
Jessberger 1988
9 Chesapeake (U.S.A.)
90
35.3
0.2
stratigraphic
Poag and Aubry 1995
10 Popigai (Russia)
100
35.7
0.8
~ArFAr
Bottomley et al. 1997
11 Wanapitei (Canada)
7.5
37
2
K/Ar
Winzer et al. 1976
12 Mistastin (Canada)
28
38
4
4°Ar/3~Ar
Mak et al. 1976
13 Logoisk (Russia)*
17
40
5
stratigraphic
Masaitis et al. 1980; Grieve et al. 1995
14 Chiyly (Kazakhstan)
5.5
46
7
?
Grieve et al. 1995
15 Kamensk (Russia)
25
49.2
0.2
4°ArfgAr
Izett et al. 1994
16 Montagnais (Canada)
45
50.5
0.8
4°ArfgAr
Bottomley and York 1988
17 Ragozinka (Russia)*
9
55
5
stratigraphic
Vishnevsky and Lagutenko 1986
18 Marquez (U.S.A.)
13
58.3
2
fission track; stratrigraphic
McHone and Sorkhabi 1994; Sharpton and Gibson 1990
19 Chicxulub (Mexico)
180
64.98
0.05
4°Ar/~Ar
Swisher et al. 1992
20 Kara (Russia)
65
70.3
2.2
4°Ar/39Ar
Trieloff et al. 1998
21 Ust Kara (Russia)
25
70.3
2.2
4°Ar/39Ar
Trieloff et al. 1998
22 Manson (U.S.A.)
37
74.1
0.1
~°ArfgAr
Izett et al. 1998
23 Lappaj5rvi (Finland)
23
77.3
0.4
4°Ar/39Ar
Jessberger and Reimold 1980
24 Boltysh (Ukraine)*
24
88
3
K/Ar
Boiko et al. 1985
25 Dellen (Sweden)
15
89.0
2.7
Rb/Sr
Deutsch et al. 1992
26 Steen River (Canada)
25
95
7
K/Ar
Carrigy 1968
27 Avak (U.S.A.)
12
100
stratigraphic
Kirschner et al. 1992
5
55
28 Carswell (Canada)
39
115
29 Mien (Sweden)
9
121.0
30 Tookoonooka (Australia)
55
31 Gosses Bluff (Australia) 32 Mj¢lnir (Barents Sea)
10
4°ArPgAr
Bottomley et al. 1989
2.3
4°Ar/39Ar
Bottomley et al. 1989
128
5
stratigraphic
Gorter et al. 1989
22
142.5
0.8
~°Ar/39Ar
Milton and Sutter 1987
40
143.1
0.8
stratigraphic
Dypvik et al. 1996; H. Dypvik, pers.comm. 1999
33 Morokweng (South Africa) >80
144.7
1.9
2°spbf32Th
Koeberl et al. 1997c
34 Puchezh-Katunki (Russia)
80
167
3
stratigraphic
Masaitis 1999
35 Obolon (Ukraine)
15
169
7
4°Ar/39Ar
Masaitis 1999
36 Red Wing (U.S.A.)
9
200
25
stratigraphic
Brenan et al. 1975; Koeberl et al. 1996b
37 Manicoaugan (Canada)
100
214
1
U/Pb
Hodych and Dunning 1992
38 Saint Martin (Canada)
40
219
32
Rb/Sr
Reimold et al. 1990
39 Araguainha (Brazil)
40
245
3
4°Arp9Ar
Hammerschmidt and Engelhardt 1995
40 Kursk (Russia)
5.5
250
80
stratigraphic
Masaitis 1999
Note: * Masaitis (1999) lists the following ages for these structures, but without giving any source for these values: Logoisk, 30 _+5 Ma; Ragozinka, 46 _+ 3 Ma; Boltysh, 95 + 10 Ma
2 Distal Ejecta and Tektites
Distal ejecta are, by definition, those ejecta that occur at considerable distances from the source crater (>5 crater radii from the crater rim; see, e.g., Melosh 1989). They either consist of (usually fine-grained) rock and mineral fragments or are of glassy consistency. It is often not immediately possible to recognize that they are directly connected to a specific impact structure. However, distal ejecta can act as a guide to major impact events and even lead to the discovery of large impact structures (Sect. 2.3). In this chapter we will review mainly glassy distal ejecta (with tektites being the main representative of this class), whereas Chap. 3 deals with the characteristics and importance of lithic distal ejecta.
2.1 Characteristics of Proximal and Distal Ejecta During crater formation, at the end of the excavation stage, about 90% of all material ejected (excavated) from the crater will be deposited relatively close to the crater (less than about 5 crater radii) and is called proximal ejecta. The mass of the ejecta decreases outwards: about half of the ejected material can be found within about one crater radius from the rim. At this proximity ejecta blankets can be up to several hundred meters thick, depending on the size of the crater. Further away the ejecta blankets become increasingly thinner and discontinuous. Comparison of data from impact experiments with those of chemical and nuclear explosion shows that at least 90% of all material ejected from a crater is deposited at a distance of 5 crater radii from the center of the structure (Fig. 2. h 1.). Most material is ejected from the crater in ballistic trajectories to a distance (range) R b, which, for short distances, follows the simple formula: Ru = (v2o/g)sin(2qb) where v e is the ejection velocity, g is the surface acceleration of gravity, and ~ is the ejection angle. If the range becomes a significant part of the radius of the planet on which the event occurs, the relations become more complicated because of the curvature of the planet (Melosh 1989, p. 87). There is a significant difference in the ejection and distribution mechanisms for craters formed with and without an atmosphere. On an airless planet, ejecta will be emplaced ballistically. Many studies on ejecta behavior were done on lunar craters (see review by Oberbeck 1975). Ejection of large blocks of target material may
58
lead to the formation of proximal secondary craters, which are - in contrast to the main crater - the result of low-velocity impacts. Calculations and experiments show that (as might be expected) not only the total ejecta mass decreases with increasing distance from the crater, but also the average particle size decreases.
1.0 0.8 _/~ f LLI 0.6 0 c 0 0.4 LL 0.2
/
/
J f
/
//~/[=
"~boratory Impact Crater
Nuclear Crater
I
2
4
6
8 10
20
30
Crater Radii Fig. 2.1.1. Proportion of ejecta mass shown in relation to distance from crater center, as deduced from laboratory impact as well as nuclear explosion crater experiments (data after Oberbeck 1975).
Ejection of material from a crater is a complicated, multistage process. Some material is ejected early on during the contact and compression stage at very high velocities (which can reach more than one third of the impact velocity; Melosh 1989), but most material is ejected during the excavation phase under much lower conditions of stress. The material seems to be ejected at relatively low angles, with very little material being thrown out at angles of more than 45 ° (Oberbeck 1975). On Earth (or another planet with an atmosphere), ejecta near the crater can also be deposited in a base surge, which is a gravity-driven density current (composed of air and dust entrained by the fireball) that flows down (and outwards) from the expanding mushroom-shaped cloud. All ejecta are subject to subsequent erosion (e.g., Grant and Schultz 1993), unless they are rapidly covered by sediments. An important conclusion from models (Oberbeck 1975) is that material launched early in the crater formation will still be in flight after the crater is completely excavated and after the more massive local ejecta have been deposited to form the continuous deposits around the crater. Thus, material ejected late in
59
the crater formation (when the shock wave has already decayed somewhat) is ejected at lower velocities and will be deposited first and close to the crater rim, whereas material ejected early and at higher velocities will be deposited later and at greater distances. The low velocity ejecta deposited at the crater rim often preserve the initial stratigraphic relationship, which leads to the inverted stratigraphy (the overturned flap) at the crater rim (because material from greater depth at the target is deposited last on the rim). This also means that material that is at greater stratigraphic depth at a crater location will, in general, be deposited close to the crater, whereas distal ejecta more commonly consist of the uppermost stratigraphic layers of the target. The higher energies available early in the crater formation sequence make it also more likely that the earliest ejecta are molten or at least strongly shocked, while the later ejecta may only be slightly shocked or not at all. On Earth the interaction with the atmosphere complicates matters somewhat. Early ejecta may also be entrained in the rapidly expanding fireball and, if the event is large enough, they will be ejected outside of the atmosphere, leading to a global distribution. Size sorting will result in larger particles settling out first and finer dust being deposited later. There are several different empirically derived formulas that describe the thickness of ejecta blankets with distance from the crater (McGetchin et al. 1973; Strftier et al. 1975; see Melosh 1989, p. 90). One of the most commonly used ones, after McGetchin et al. (1973), gives a power law for the ejecta blanket thickness t as a function of distance r from the crater center: t = 0.14R°Ta(r/R) 3.0for r • R where R is the radius of the transient cavity and dimensions are in meters. The exact values for the function of R are debated, and Melosh (1989) proposed a more general version in which the term 0 . 1 4 R °74 is replaced by f(R), a poorly defined function that depends on a variety of parameters and may be different for different planets. From the study of the distribution of microtektites in the Australasian strewn field, Glass and Pizzuto (1994) arrived at a modified relation: t = 0.02R(r/R) ~4±°3 which can be rewritten as a function of the distance alone: t
= 1024°-+°4r -44-+°3
Whereas the original relations seem to have been deduced from proximal ejecta, it seems that this formula, with somewhat different coefficients, also describes the distribution of distal ejecta. A glance at the full Moon through binoculars shows an interesting feature aJ:ound some craters: the very conspicuous so-called crater rays, which are bright radially-oriented streaks along approximately great circles, originating from some craters. For example, the crater rays from the lunar crater Tycho extend almost across the whole visible hemisphere. Only the younger and fresher craters seem to have rays (Melosh 1989). The maximum radius R r of an average ray pattern on the Moon has been described as a power function of crater diameter R, where
60
10.5R 125,but individual ray systems may be larger or smaller than the formula would indicate. The nature and source of the rays is poorly understood. It is not clear if the material that forms the rays comes from deeper zones of the target or from near-surface layers. Explosion experiments have shown that jets of highvelocity gas seem to be forming patterns similar to those of crater rays, which could explain a role of the expanding vapor cloud in their formation. Crater rays have only been observed on airless bodies (e.g., Moon, Mercury), either because the atmosphere prevents their emplacement or because they are eroded soon after their formation, but it is tantalizing to speculate if some distal ejecta on Earth may not be the result of a ray-like formation process (see Sects. 2.4.1. and 2.4.6.). Clearly the atmosphere influences the distribution of proximal ejecta (e.g., Kring 1997; Barnouin-Jha and Schultz 1998), so possibly there is also an interaction during distal ejecta emplacement.
R r =
2.2 Distal Ejecta as Stratigraphic Markers Distal ejecta can serve as markers for impact events in the stratigraphic record. "Impact markers" can be described as all chemical, isotopic, and mineralogical species derived from the encounter of cosmic bodies (such as cometary nuclei or asteroids) with the Earth. They include material derived directly from the extraterrestrial bodies (siderophile elements, rare gases, meteoritic minerals) and species resulting from mechanical and physical interaction between the impactor and the target (e.g., shock-metamorphosed minerals and rocks). Such markers are of prime importance to detect and study accretionary events in the sedimentary record, to identify their origin, and to evaluate their possible role in global change and on the Earth's biotic and climatic evolution throughout geological time (see Sect. 5.1). Distal ejecta layers are better suited to study a possible relationship between biotic changes and impact events, as the direct correlation can be confirmed in the stratigraphic record, whereas a correlation with radiometrically determined crater ages always suffers from uncertainties in age determinations. There is a variety of the different types of stratigraphic impact markers. In principle, the concept behind interpreting them is similar as for volcanic markers in the stratigraphic record, such as biotite and other typical volcanogenic minerals (or shards of volcanic glass). Such volcanic markers have various functions. They often provide an excellent means for obtaining radiometric ages for a stratigraphic sequence that consists of, e.g., carbonate rocks that are otherwise difficult to date directly (see Chap. 5 for several examples). This allows then to tie in the biostratigraphic record with direct radiometric ages. By studying the composition of mineral and glass fragments in such volcanogenic layers it is also often possible to determine from which volcano these materials had been erupted. Impactoclastic layers may be studied in similar ways. Impactoclastic layers are composed of distal ejecta. For example, tektites and microtektites are glassy ejecta that are described in detail in Sect. 2.4. The occur-
61
fence of microtektites in well-defined and thin layers in deep-sea sediments provides an excellent time marker and means for correlation the stratigraphy between different locations (e.g., Zhou and Shackleton 1999). The study of ejecta at the K/T boundary or in southern Australia eventually led to the discovery of previously unknown large impact structures (Chicxulub and Acraman, respectively). In other cases, comparative analyses of the composition and age of tektites and/or microtektites and rocks at specific crater sites led to the determination of tektite source craters (e.g., Ivory Coast tektites and Bosumtwi crater - see Sect. 2.4.5.3). Another example for the study of potential impact markers involves the search for material resulting from the 1908 airblast at Tunguska, Siberia, where most likely a stony body (if of chondritic/asteroidal or cometary provenance is not yet clear) exploded in the air (see Sect. 1.4), distributing cosmic dust over a wide area. At the airblast site, minor amounts of extraterrestrial dust were found to be mixed in with local soil (e.g., Rasmussen et al. 1999), but it was debated if any such signature could also be detected elsewhere around the world. Ganapathy (1983) claimed to have found Tunguska-derived extraterrestrial material in ice near the South Pole, whereas other studies (e.g., Roccbia et al. 1990; Rasmussen et al. 1995) found no such evidence. The studies of the K/T ejecta layers led to improved detection sensitivities for impact markers, allowing identification of smaller events and the study of their effects. A very promising example has been detected in terminal Eocene sediments, as described in Sect. 5.8.4. The most commonly used impact markers are elevated contents of siderophile elements (especially the Ir and other PGEs; e.g., Asaro et al. 1982, 1988; Orth et al 1988, 1990; Alvarez et al. 1990; see Sect. 1.8.1) and the presence of shocked minerals, especially quartz. However, more recently a number of other markers have been identified that seem to be characteristic of impact. For example, Ni-rich spinels (Fig. 2.2.1) have been found in several impactoclastic layers (e.g., Kyte and Smit 1986; Robin et al. 1992; Gayraud et al. 1996; Rocchia et al. 1996b; Pierrard et al. 1998). Robin et al. (1999) report on finding several spinel-bearing horizons in a core from the Central Pacific Ocean, which may be related to several different impact events. Impact-derived diamonds have been found at different K/T boundary locations around the world (e.g., Carlisle and Braman 1991; Hough etal. 1997, 1998), but the problem with using diamonds as impact markers in distal ejecta is that, so far, they have only been found in terrestrial or relatively shallow-water and proximal K/T boundary sites (however, they have been found within proximal ejecta at several impact structures; see Sect. 1.6.7). Another geochemical marker possibly associated with impact events is the presence of fullerenes (Becker et al. 1994), which have been found in K/T boundary samples (Heymann et al. 1994, 1996), although their origin (if extraterrestrial or produced in the impact fireball) is disputed (Becker et al. 1996; Heymann et al. 1996). Recently, Chijiwa et al. (1999) reported on the discovery of fullerenes in a Permo-Triassic boundary section (see Sect. 3.6.3).
62
Fig. 2.2.1. Secondary electron microscope photo of spinel (magnesioferrite) from the K/T boundary in Caravaca, Spain, which is a reliable impact marker (photo courtesy B.F. Bohor).
Not all markers that are characteristic of extraterrestrial material are impactderived. Extraterrestrial material accretes in the form of meteorites and cosmic dust onto the Earth (e.g., Kyte and Wasson 1986; Kyte et al. 1993), and it is possible that there are times at which this accretion rate increases significantly (e.g., Schmitz et al. 1997). The recent discovery of cosmic spherules in 1.4 Ga sandstone from Finland (Deutsch et al. 1997) leaves open the question of whether or not these spherules are just well preserved by chance or if they are the result of an increase in the accretion rate. Of particular interest are high 3He concentrations that are known to be associated with interplanetary dust, which have been identified, for example, in upper Eocene sediments from the Pacific and Italy (Farley 1995; Farley et al. 1998; see Sect. 5.8.4). These data indicate a general and significant increase of the flux of extraterrestrial matter onto the Earth during an extended period of a few million years. This period coincides with at least two large impact events (Popigai and Chesapeake Bay), but the 3He does not result directly from the impacts. The elevated 3He flux was ascribed by Farley and coworkers to increased amounts of interplanetary dust in the inner solar system as a result of a cometary shower, which also included the impact of the bodies that formed the Chesapeake Bay and Popigai structures.
63
Thus, the study of impact markers in the sedimentary record, and, more specifically, at various paleontological boundaries, is an important component of impactrelated research and may bring about the discovery of several previously unknown impact events and structures. Analysis of impact markers yields important information regarding the physical and chemical conditions of their formation, such as temperature, pressure, oxygen fugacity, composition of the atmosphere. These data are necessary to understand the mechanisms of interaction of impact events with the environment (see also Sect. 5.1).
2.3 Importance of the K/I" boundary We have already mentioned in several other places in this book that the study of rocks from the K/T boundary layer has been one of the most important driving forces for impact research in the past decades (cf. Grieve 1982). The K/T boundary can also serve as an example of how the various types of distal ejecta can be correlated with proximal ejecta and, eventually, an impact structure. It was by measuring the concentration of the element iridium, a specific marker of extraterrestrial material, in the sediments from the K/T boundary that provided the first direct evidence for a large impact event at the end of the Cretaceous. This led, in turn, to the theory that the mass extinction of the end of the Cretaceous was caused by a huge asteroid or comet impact. Furthermore, by studying the various impact markers at K/T boundary locations around the world, the Chicxulub impact structure on the Yucatan Peninsula, Mexico, was discovered. The study of shocked zircons and of impact glasses from the K/T boundary helped to establish the link to the Chicxulub crater (see Sect. 3.2). Studies of impact markers, together with high-resolution paleontological investigations, indicate that it is quite possible that there is a causal link between the impact event and the biologic crisis of the end of the Cretaceous. Studies of the K/T boundary event provided data that helped with the understanding of the origin and significance of other, possibly impact-related, boundaries and exotic layers in the stratigraphic record. The impetus and publicity derived from K/T boundary research helped to introduce impact research to the wider geological community, and planetary geologists, who had been working on similar topics for decades (but outside the scope of the general geological community), were able to provide their results (e.g., from tektite studies or shock experiments) for the interpretation of the events that marked the end of the Cretaceous. As such, K/T boundary research played several important roles: increase the visibility and acceptance of impact research, and provided applications for decades of impact research. Data gained from, for example, research on tektites were useful in interpreting some aspects of the K/T boundary, and, in reverse, methods and concepts resulting from K/T studies aided with the interpretation of tektite data. In addition, the evidence that an impact event is associated with at least one major
64
geological boundary has led to speculation - and more research - about the causes of other geological boundaries (see Sect. 3).
2.4 Tektites and Microtektites Tektites are a group of natural glasses that have puzzled mankind for many centuties. After centuries of collecting, and decades of study, we are now closer to an understanding of their origin. First, though, we need to describe what tektites are. They are chemically homogeneous, often spherically symmetric objects that are in general several centimeters in size, and occur in four known strewn fields on the surface of the Earth. Strewn fields can be defined as geographically extended areas (in the case of tektites larger than just a few square kilometers) over which tektite material can be found. Tektites found on land have traditionally been subdivided into three groups: (a) normal or splash-form tektites, (b) aerodynamically shaped tektites, and (c) Muong Nong-type tektites (sometimes also called layered tektites). The first two groups differ only in their appearance and some of their physical characteristics (see, e.g., O'Keefe 1963; Chao 1963; O'Keefe 1976). The aerodynamic ablation results from partial re-melting of glass during atmospheric re-entry after it was ejected outside the terrestrial atmosphere and solidified through quenching. Aerodynamically shaped tektites are known mainly from the Australasian strewn field, where they occur primarily as flanged-button australites (Fig. 2.4.1a, b). The shapes of splash-form tektites (spheres, droplets, teardrops, dumbbells, etc., or fragments thereof; Fig. 2.3.2a-c) have sometimes erroneously been described as aerodynamical forms; they, however, result from the solidification of rotating liquids, and not atmospheric ablation. Muong Nong type tektites were named after the type-locality in Laos (Lacroix 1935). They are usually considerably larger than normal tektites (samples of up to 24 kg have been described; Koeberl 1992a) and are of chunky, blocky appearance. Muong Nong-type tektites show a layered structure with abundant vesicles (Fig. 2.4.3). Microscopic examination of the layers (Fig. 2.4.4) shows bands of lighter and darker color (which should not be confused with schlieren) and mineral inclusions, such as zircon, baddeleyite, chromite, ruffle, corundum, and cristobalite (Glass 1970, 1972; Glass and Barlow 1979; Glass et al. 1990, 1995) and coesite (Walter 1965) have been described from Muong Nong-type tektites. Mainly due to chemical studies, it is now commonly accepted that tektites are the product of melting and quenching of terrestrial rocks during hypervelocity impact on the Earth. The chemistry of tektites is in many respects identical to the composition of upper crustal material (Taylor 1973; Koeberl 1986). Trace elements are very useful for source rock comparisons: many trace element ratios in tektites are indistinguishable from those in upper crustal rocks. The chondritenormalized REE patterns of tektites are very similar to those of shales or loess, and have the characteristic shape and total abundances of the post-Archean upper
65
crust. The determination of the exact source rocks of tektites is complicated because a variety of target rocks was apparently sampled by each impact event. The discussion in the following chapters follows m a i n l y Koeberl (1994b), with recent updates.
3
b Fig. 2.4.1. a) Four small, aerodynamically shaped tektites from Australia (australites). The sampies on the right and the second from the left show the typical button-shape with an ablation flange (samples courtesy H. Stehlik). b) Broken flanged australite, seen from the underside (sample USNM 3468).
66
cm
a
Fig. 2.4.2. Variety of splash-form tektites from the Australasian strewn field: a) teardrops from Guangxi (China); b) spherical and dumbbell tektites from Thailand; c) (next page) four dropshaped thailandites (samples courtesy H. Stehlik).
67
p
L k k
c!\
•
Fig. 2.4.3. Muong Nong-type (or layered) tektite from Indochina. The scale bar (1 cm) is barely visible below the center of the sample. The layered structure with different colors and large vesicles is obvious (sample courtesy H. Stehlik).
68
Fig. 2.4.4. Muong Nong-type indochinite (from Thailand). Thin slice (ca. 1.5 mm thickness) seen in transmitted light, showing the inhomogeneity and the different colored layers that are somewhat deformed. Bubbles are cut and, therefore, are slightly overexposed. Width of image about 10 cm.
2.4.1 Geographical Distribution: Strewn Fields and Age So far, tektite occurrences are known from four geographically extended strewn fields (Fig. 2.4.1.1): the North American, Central European (moldavite), Ivory Coast, and Australasian strewn fields (Barnes 1963a; O'Keefe 1963). Tektites found within each strewn field are related to each other with respect to their petrological, physical, and chemical properties as well as their age. Ages of tektites have usually been determined by the K - A r method (e.g., Zahringer 1963; Gentner 1969a), fission-track dating (e.g., Gentner et al. 1969b, 1970; Storzer and Wagner 1969, 1971, Storzer et al. 1973), or the A r - A r technique (e.g., Glass et al. 1986b; Izett and Obradovich 1992; Bollinger 1993). Koeberl (1994b) provided a summary of the properties of tektites found in the four known strewn fields. Any discussion of the origin of the tektites needs to explain the similarity of tektites in respect to age and certain aspects of isotopic and chemical composition within one strewn field as well as the existence of tektite material with different compositions
69
present in each strewn field (Taylor 1973; King 1977; Koeberl 1986, 1988, 1989a, 1990). The occurrence of tektite glasses is not restricted to the continents. Since the mid-1960s, microtektites from three of the four strewn fields have been found in deep-sea cores (see, e.g., Glass 1967, 1968, 1969, 1972; Cassidy et al. 1969). They are generally less than 1 mm in diameter and show a somewhat wider variation in chemical composition than tektites on land but with an average composition that is very close to that of "normal" tektites. Microtektites have been very important for defining the extent of the strewn fields (Fig. 2.4.1.1), as well as for constraining the stratigraphic age of tektites, and to provide evidence regarding the location of possible source craters. Some new finds of tektite material on Barbados and at DSDP Site 612 samples (see, e.g., Thein 1987; Koeberl and Glass 1988; Glass 1989) have yielded larger "micro'tektites as well as what seem to be fragments of tektites, and blur the traditional distinction between microtektites and "macro"tektites.
2.4.2 Definition and Classification of Tektites The recent discoveries of impact-derived glasses in various geological contexts, and from various sources, led to the unfortunate habit of some researchers to term all impact-derived glasses (and even non-glassy, recrystallized objects) "tektites" (e.g., Claeys et al. 1992; Izett 1991; Smit et al. 1992a, b). However, there are some differences between tektites and impact glasses from known impact craters. Table 2.4.2.1 provides a comparison of the characteristics of tektites and impact glasses. Although tektites have of course formed during an impact event, they are a subgroup of impact glasses in general; maybe a possible distinction would be to call tektites "distal impact glasses", in contrast to "proximal impact glasses" that are found directly at a source crater. The "definition" of a tektite has a somewhat historic aspect, but a short summary of the characteristics of tektites would include the following points: t) they are glassy (amorphous); 2) they are fairly homogeneous rock (not mineral) melts; 3) they contain abundant lechatelierite; 4) they occur in geographically extended strewn fields (not just at one or two closely related locations); 5) they are distal ejecta and do not occur directly in or around a source crater, or within typical impact lithologies (e.g., suevitic breccias, impact melt breccias); 6) they are very poor in water (except some microtektites) and have a very small extraterrestrial component; and 7) they seem to have formed from the uppermost layer of the target surface (see Sects. 2.4.4 and 2.4.6). Thus, it is recommended to use the term "tektite" only for glasses that fulfill (most) of the above points, and, if in doubt, use the (probably much better) general term "impact glass".
70
t,
~
~
en
for)
"F-._
Ec
Fig. 2.4.1.1. Location and extension of the four tektite strewn fields on Earth. The solid circles mark the location of the known source craters (Chesapeake Bay, Ries, and Bosumtwi craters) and the suspected crater location for the Australasian strewn field.
71
Table 2.4.2.1. Comparison of tektites and "normal" impact glasses. Tektites
"Normal" Impact Glasses
Occurrence in strewn field
Yes
no
Source crater known
yes/no*
yes
Occurrence at source crater
No
yes
Chemical homogeneity (100 ~tm-mm)
large-scale homogeneity
usually inhomogeneous
Water content (wt.%)
0.002~).02
0.02-0.07
Mineral inclusions
very rare
generally abundant (include partly digested quartz)
Shape
mostly regular spherically symmetric
mostly irregular
Ablation shapes
some do
no
Meteoritic component
very small
generally higher; variable
Heavy noble gas content (Ar, Kr, Xe)
generally lower
generally higher
Note: *knowledge of source crater reflects present knowledge; all tektite strewn fields have a source crater. Table after Koeberl (1994b).
2.4.3 Petrology and Geochemistry of Tektites The geochemical and petrological characteristics of tektites provide an important background for the debate about source and formation mechanism of these glasses. W e follow the assumption that the geochemistry of tektites provides information on the geochemistry of the source rocks, from which the tektites were produced. Reviews of this subject, as well as detailed tables of the major and trace element composition of all tektite groups, have been published by Chao (1963) and Koeberl (1986, 1990, 1992a, 1994b, and references therein); thus, we will only provide a short review here. In general, the major and trace element composition of tektites is almost identical to the composition of the terrestrial upper crust. This fundamental observation was made mainly by Taylor and co-workers, who, during the 1960s and 1970s, have performed detailed geochemical studies of many tektite types (see, e.g., Taylor 1962a, b, 1966, 1973; Taylor and Sachs 1964, Taylor and Solomon 1964, Taylor and Kaye 1969, and Taylor and McLennan 1979). Of particular use in establishing such a relationship are trace elements: the ratios of, e.g., Ba/Rb, K/U, Th/Sm, Sm/Sc, Th/Sc, K vs. K/U, in tektites are practically the same as those in
72
upper crustal rocks. As a result of mainly these chemical studies, it is now commonly accepted that tektites are the product of melting and subsequent quenching of terrestrial rocks during hypervelocity impact on the Earth. One group of elements that have great genetic significance are the rare earth elements (REE), because geochemically they behave very similar to each other. Their absolute abundances, as well as their chondrite-normalized abundance patterns, are characteristic for different rock types of different provenance (e.g., Taylor and McLennan 1985). Thus, they can be used to infer the type and composition of the tektite parent rocks. The chondrite-normalized REE patterns of tektites are very similar to those of shales or other upper crustal sedimentary rocks, and have the characteristic shape and total abundances of REE distributions in the post-Archean upper crust. Fig. 2.4.3.1 shows an example of such a chondritenormalized REE pattern. It has been discussed before (e.g., Koeberl 1986, 1990, 1992a, 1994b) that the average REE patterns of post-Archean upper crustal rocks are different from those of Archean upper crustal rocks, with post-Archean sediments showing a characteristic negative Eu anomaly that is absent from Archean sediments (e.g., Taylor and McLennan 1985). This is also visible in Fig. 2.4.3.1 and demonstrates that Archean sediments are implausible as source materials for the four known Cenozoic tektite strewn fields. More extensive discussions of the use of REEs in tektite studies were given by, e.g., Taylor and McLennan (1979) and Koeberl (1992a, 1994b). REE analyses also indicate that loess, which is not known from Indochina, but has been proposed by Wasson (1991) as a possible source rock for tektites, was not a prominent source of the Australasian tektites (as discussed in detail by Koeberl 1992a; this was also confirmed by the R b - S r and S m - N d isotope studies of Blum et al. 1992). Also, none of the trace element ratios or REE patterns are similar to lunar or other extraterrestrial values, eliminating the lunar origin theory of tektites (e.g., O'Keefe 1976) as a viable contender (e.g., Schnetzler 1970; Taylor 1973, 1982). O'Keefe and co-workers suggested that tektites are similar in composition to lunar granites. However, they are not even similar in composition to terrestrial granites, and, furthermore, granites require water to form, which does not exist on the Moon. Granite-like residual melts on the Moon ("felsites") are very rare and small (the largest one found so far is 1.8 g), and also of a composition different from that of tektites (see discussion in Taylor and Koeberl 1994). Whereas most studies cited in the previous paragraphs deal with Australasian tektites, the same conclusions can be drawn from REE abundances and patterns of the other three tektite strewn fields. The REE patterns (as well as other trace element abundances and ratios) of North American tektites are in direct agreement with a derivation from upper crustal rocks (e.g., Koeberl and Glass 1988; Glass et al. 1995, 1998). In case of the strewn fields that have been linked to specific craters, trace element studies have strengthened the evidence for a link. For example, comparisons have been made (e.g., Engelhardt et al. 1987) between the trace element composition of upper freshwater molasse samples which were presuma-
73
bly present at the site of the Ries crater, and those of the moldavites (see Sect. 2.4.5). 100
o c
Splash-Form Australites
7o c
Muong Nong
Jo
Tektites
70 N
O Z
$ .E
"1o to tO !
|
!
ka Ce Pr Nd
!
!
!
I
!
!
|
!
i
|
l
Sm Eu Gd Tb Dy No Er Tm Yb ku
Fig. 2.4.3.1. Chondrite-normalized REE pattern of the average present (post-Archean) upper crust in comparison with the REE patterns of average Muong Nong-type tektites and average australites. The patterns are clearly very similar, with almost identical slopes, LREE/HREE or La/Yb ratios, and Eu anomalies (after Koeberl 1994b).
Muong Nong-type Tektites. Muong Nong-type tektites have first been described from the Australasian strewn field and differ from normal tektites in a few important parameters. They are larger, more heterogeneous in composition, of irregular shape, have a layered structure, and show a much more restricted geographical distribution (see, e.g., Chapman and Scheiber 1969; Futrell and Fredriksson 1983; Koeberl 1986, 1992a; Schnetzler 1992; Fiske etal. 1999; Schnetzler et al. 1999). Their average major element chemistry and their age are (within normal variations) identical to those of normal tektites. Muong Nongtypes are abundant in the Australasian strewn field, but recently a few samples that are most probably of Muong Nong-type have also been found from the Central European (e.g., Glass et al. 1990) and North American (Wittke and Barnes 1988; Koeberl and Glass 1988; Glass et al. 1995) strewn fields. Muong Nong-type tektites differ in some characteristics from "normal" tektites: they are chemically less homogeneous (including differences in composition between layers). Furthermore,
74
water (Koeberl and Beran 1988; Beran and Koeberl 1997) and other volatile elements, such as the halogens or Zn (see, e.g., Mtiller and Gentner 1973; Matthies and Koeberl 1991; Koeberl 1992a) are enriched in Muong Nong-type tektites compared to splash form tektites - or just less depleted in comparison to the source rocks. Koebert (1992a) and others have speculated that the volatile element enrichment in Muong Nong-type tektites results from lower formation temperatures than splash-form tektites. They probably formed from the same or a very similar source material, but were less thoroughly heated (see, e.g., Barnes 1990, for petrographic evidence for this statement, based on vesicularity of lechatelierite particles) and have, therefore, lost less of their volatile element content than the splash form tektites. Volatile element contents in Muong Nong-type tektites are comparable to, or only slightly lower than, the ones in upper crustal sedimentary rocks (e.g., Koeberl 1992a), while splash-form tektites show considerable depletions. Wasson et al. (1990) suggested that uranium may behave as a volatile element during tektite formation, but the observed U depletion can also result from oxidation of U 4+ to U 6+and removal as soluble [UO2] 2 (McLennan and Taylor 1980).
Table 2.4.3.1. Major element composition of Muong Nong-type indochinites compared to tektites from all four known strewn fields, and average continental crust. Muong Nong Indochinites
Australasian North Central Tektites A m e r i c a n European Tektites Tektites
SiO~ 77.1-81.7 64.8-79.7 Tit 2 0.53-0.72 0.49-1.00 A1203 8.58-11.4 8.90-17~7 FeO 3.18-4A5 3.57-8.63 MnO 0.07-0.10 0.07-0.21 MgO 1.19-1.65 1.31-7.95 Cat 1.03-1.63 1.37-9.77 NazO 0.77-1.07 0.62-1.56 K~O 2 . 2 4 - 2 . 5 5 1.34-2.81
71.9-83.6 0.42-1.05 9.50-17.6 1.83-5.75 0.02-0.08 0.37-0.95 0.40-0.96 0.70-1.84 1.60-2.51
Ivory Coast Average Tektites Continental Crust
74.9-85.1 66.2-69.3 0.24-1.40 0.52-0.61 7.32-13.8 15.8-17.7 1.08-3.50 5.84-6.80 0.03-0.09 0.04-0.07 1.13-2.74 2.64-4.39 0.95-3.17 0.71-1.61 0.20-1.08 1.53-2.44 2.23-3.81 1.70-2.08
66.0 0.50 15.2 4.50 0.08 2.2 4.2 3.9 3.4
For data sources, see Koeberl (1986, 1992a) and Koeberl et al. (1997b). All data in wt.% and all Fe as FeO. Australasian tektites include splash-form and ablation-shaped samples from Indochina, Australia, and the Philippines (except HNa/K australites, see Sect. 2.5); North American tektites include only bediasites and georgiaites.
Muong Nong-type tektites occur mainly as silica-poor and silica-rich varieties, with some samples having intermediate compositions. Table 2.4.3.1 gives the major element compositions of tektites from the four known strewn fields, as well as for different layers in Muong Nong-type tektites, and for the average upper continental crust. Koeberl (1992a) concluded that it is unlikely that Si-poor
75
Muong Nong-type tektites originated by vapor fractionation from Si-rich Muong Nong-type tektites silica, but rather that they are the result of mixing of different source rocks (which is also indicated by different relict mineral contents in Si-rich an Si-poor Muong Nong-type tektites). Muong Nong-type tektites may be the key to some important questions. Their inhomogeneity may indicate that they have preserved the original target rock compositions much better and therefore they may be the missing link between target rocks and tektites (e.g., Koeberl and Fredriksson 1986). They are also important because they contain relict mineral grains that indicate the nature of the parent material and contain shock-produced phases that indicate the conditions of formation. Microtektites. Microtekfites from the North American, Ivory Coast, and Australasian strewn fields have been recovered from deep-sea sediments (see, e.g., Glass 1967, 1968, 1969, 1972; Cassidy et al. 1969). Microtektites are, by definition, less than 1 mm in size, and show a variety of shapes (Fig. 2.4.3.2.), ranging from spherical to dumbbell, disc, oval, and teardrop. In color they range from colorless and transparent to yellowish and pale brown. They often contain bubbles and lechateliefite inclusions. Microtekfites occur in the stratigraphic layers of the deep-sea sediments that correspond in age to he radiometrically determined ages of the tektites found on land. Thus, they are distal ejecta and represent an impact marker. The geographical distribution of microtektite-bearing cores defines the extent of the respective strewn fields, as tektite occurrences on land are much more restricted. Furthermore, microtektites have been found together with melt fragments, high-pressure phases, and shocked minerals (e.g., Glass 1989; Glass and Wu 1993) and, therefore, provide confirming evidence for the association of tektites with an impact event. In addition, the geographic variation of the microtekfite concentrations in deep-sea sediments is not irregular, but increases towards the assumed or deduced impact location. For example, Glass and Pizzuto (1994) determined the geographic variation in abundance of Australasian microtektites (ranging from <1 to 3255 microtektites per cm2 in the >125 ~tm size range), and found that the abundances increased towards Indochina; and deduced a possible source region in Cambodia. Also, the distribution of microtektites in the strewn field is not uniform, but may follow some kind of ray-like pattern. Recently, microtektites have been discovered on land in loess at Luochuan in China, slightly north of the commonly drawn limits of the strewn field (Li et al. 1993, 1995). Their stratigraphic occurrence near the Brunhes-Matuyama boundary and their composition indicate that they are indeed part of the Australasian strewn field. The composition of most microtektites shows a similar (but somewhat more extended) range than tektites on land of the same strewn field. Besides the wider compositional range there is also a slight difference in the mean composition between the two groups (e.g., Bohor and Koeberl 1996), but it is not clear if this results from a difference in the origin (or location in the target stratigraphy), or could be due to different analytical methods used for their study. The analyses of normal tektites are usually performed as bulk analyses, whereas microtektites are
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analyzed by electron microprobe. On a micrometer-scale, larger tektites are often more inhomogeneous than individual microtektites (Delano 1992; B.P. Glass, pets. comm. 1993).
Fig. 2.4.3.2. Microtektites from the Australasian tektite strewn field, showing a variety of shapes. A so-called bottle-green microtektite is near the center of the image. Width of image 2.7 mm (photo courtesy B.P. Glass).
There is a group of highly unusual microtektites, the so-called bottle-green microtektites or high-Mg (HMg) microtektites (Glass 1972), which have a composition that is different from that of "normal" microtektites. They are green, corroded in appearance (Fig. 2.4.3.3), do not contain bubbles or lechatelierite inclusions, and are poor in Si and high in Mg. These glassy spherules are generally smaller than normal microtektites, but do not seem to show a different spatial distribution. The average composition of BGMTs is different from that of normal microtektites, tektites on land, or the average continental crust. Koeberl et al. (1999a) found not only significant enrichments in Mg, but also enrichments in Ti, Ca, Sc, St, Zr, Ba, Hf, Ta, W, Th, and the rare earth elements, and depletions in Si and the alkali elements, in comparison with average tektites. Importantly, the BGMTs show very high abundances of the siderophile elements (Cr, Co, Ni, and Ir). Up to about 10 ppb Ir were found (Koeberl et al. 1999a). These values are taken as a clear indication of an extraterrestrial component. Boron isotope measurements show vapor
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fractionation effects and a starting composition that seems to be compatible only with the B isotopic composition of soil. From these data, Koeberl et al. (1999a) proposed that the BGMTs formed in the earliest phases of the tektite-forming impact, possibly by some form of jetting, from the uppermost part of the target stratigraphy.
Fig. 2.4.3.3. Microphotograph of a bottle-green microtektite from the Australasian strewn field. Note the corroded appearance of the sample, in contrast to the smooth surfaces of normal microtektites (sample size about 250 I.tm;photo courtesy B.P. Glass).
Inclusions of Relict Minerals and Shock Phases. The occurrence of relict minerals in some tektites points to sedimentary source rocks. Lechatelierite - the amorphous remainder of partly digested quartz grains - is well-documented in tektites (e.g., Chao 1963) and indicates quartz-rich precursor rocks. Lechatelierite is also common in microtektites. Muong Nong-type tektites contain unmelted relict inclusions (Barnes 1963b; Glass 1970, 1972; Glass and Barlow 1979). The minerals identified so far include zircon, chromite, quartz (Glass 1970), ruffle, and monazite (Glass 1972), all showing evidence of various degrees of shock metamorphism. They also contain high-temperature breakdown products, such as co-
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rundum (plus SiO2), which formed from an AleSiO5 phase, and baddeleyite (plus SiO2), which formed from zircon (e.g., Glass and Barlow 1979; Glass et al. 1990, 1995). Muong Nong-type indochinites can be divided into two groups: those with low refractive indices (<1.503) contain mineral inclusions while those with high refractive indices (>1.513) do not (Glass and Barlow 1979; Glass and Koeberl 1989). The type of mineral inclusions present, as well as their size and shape, suggests that a fine-grained, well-sorted sediment was the tektite parent material.
Fig. 2.4.3.4. Backscattered electron image of a partly decomposed zircon inclusion in a Muong Nong-type tektite from Indochina.
The high-pressure quartz polymorph coesite has been reported from Muong Nong tektites by Walter (1965) and was confirmed by Glass et al. (1986a). It also had been found in Darwin glass (Reid and Cohen 1962). Glass (1987) and Bohor et al. (1988) found coesite and shocked minerals associated with tektites in a layer containing an impact debris, tektite fragments, and microtektites at DSDP Site 612 in the North American tektite strewn field, supporting the association of tektites with shocked minerals. Stishovite has also been reported from the North American and Australasian microtektite layers (Glass 1989; Glass and Wu 1993).
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2.4.4 Source Rocks of Tektites The discussion presented above on the composition of (and inclusions in) tektites and microtektites makes it clear that only terrestrial upper crustal rocks are plausible as source rocks of tektites. Trace element data have narrowed the choice to post-Archean sediments. Further refinement is possible from the determination of abundances and ratios of various isotopes in tektites. One of the first isotopic studies was performed by Tilton (1958), who analyzed the isotopic composition of lead in tektites and found it to be in agreement with terrestrial values. Similar conclusions were obtained by Schnetzler and Pinson (1964) for Rb/Sr and by Taylor and Epstein (1969) for oxygen isotopes. There are indications that the isotopic composition of oxygen in some tektites (e.g., moldavites; see Engelhardt et al. 1987) is skewed towards the lighter isotopes in tektites compared to source rocks. This effect may be due to incorporation of isotopically light oxygen from meteoric water which resides in pores of sediments (Engelhardt et al. 1987). In contrast, Koeberl et al. (1998b) found no evidence for any modification of oxygen isotope values for Ivory Coast tektites. These tektites have 5180 values that are virtually identical to those of target rocks from the Bosumtwi crater (see below). Shaw and Wasserburg (1982) demonstrated that all tektites have distinct negative end and large positive es~ values, which are uniquely characteristic of old terrestrial continental crust. The Nd model ages of tektites reflect the age of the source terrain of the target rocks, i.e., the age during partial melting of the mantle to form new crust. Surficial processes, such as weathering, do not disturb the SmNd isotopic system. However, the Rb-Sr isotopic system is severely disturbed by increasing the Rb/Sr ratio during weathering and sedimentation. The Rb-Sr sedimentation age of tektites shows a wide variation, ranging from young sediments for the Central European tektites (recent at the time of the impact; i.e., at 15 Ma) to rocks of about 0.95 Ga for the Ivory Coast tektites. For the North American tektites, the Rb-Sr/Sm-Nd systematics exclude most of the North American Precambrian shield areas as well as areas that are covered by sediments derived from them. Shaw and Wasserburg (1982), Ngo et al. (1985), and Stecher et al. (1989) concluded that sediments derived from, or incorporated in, the Appalachian orogeny provide the best match for North American tektites. This fits very well with the recently discovered Chesapeake Bay crater, which was recently concluded to be the source crater of the North American tektites (see Sect. 3.3.1). From a study of the Rb-Sr and Sm-Nd isotopic systematic of Muong Nongtype and splash-form tektites from the Australasian strewn field, Blum et al. (1992) found that the source material was derived from Precambrian crustal terrane with Nd model ages ranging from 1040 to 1190 Ma. The Rb-Sr system indicates that the sediments that were later melted to form tektites were weathered and deposited about 167 Ma ago and probably comprised Jurassic sediments, which are not uncommon throughout Indochina. The Nd and Sr isotopic data suggest that all Australasian tektites were derived from a single sedimentary formation with a narrow range of stratigraphic ages close to 170 Ma, more or less ruling out multi-
80
ple impact hypotheses (e.g., Wasson t991). Blum et al. (1992) also concluded from their data that the Rb-Sr isotope systematics are inconsistent with soil or loess as source materials. Other isotopic systems, such as boron, carbon, nitrogen, magnesium, or sulfur, have not yet been explored in detail or at all, mainly due to analytical problems caused by the low concentrations of these elements. A study of 81'B in tektites by (Chaussidon and Koeberl 1995) showed most tektites have a limited range (-9.3 _+ 1.5%o to +2.7 + 1.5%0, which is small compared to the range observed for common terrestrial rocks (-30 to +40%0). The B abundance and isotopic data can he used to place constraints on the tektite source rocks. Australasian tektites have high B and Li abundances; only clay-rich sediments, such as pelagic and neritic sediments, as well as fiver and deltaic sediments have B contents (up to 100 ppm) and ~511Bvalues that are in agreement with the range shown by Australasian tektites (-4.9 to +1.4%0. ~°Beand Rb-Sr data indicate continental crustal source rocks and exclude pelagic and neritic sediments. However, deltaic sediments, e.g., from the Mekong river, which are of continental crustal origin, agree with ~°Be, Rb-Sr, and B data, and support a possible source locality close to the coast of SE Indochina in the South China Sea. The examples given above demonstrate that there is great potential in the use of various isotope system for tektite studies.
2.4.5 Source Craters of Tektites Initially, when tektites were first discovered in the various strewn fields, their origin was a mystery. The studies discussed in the previous sections lead to the conclusion that tektites were formed during hypervelocity impact into postArchean upper crustal rocks. This conclusion raised the question regarding source craters. During the past half century, numerous suggestions and educated guesses have been made regarding the location of the possible source craters for the tektite strewn fields. Relatively reliable links between craters and tektite strewn fields have been established between the Bosumtwi (Ghana) and the Ries (Germany) craters and the Ivory Coast and the Central European fields, respectively. Only recently, a plausible link was established between the newly discovered Chesapeake Bay crater and the North American strewn field. No large crater with an appropriate age has yet been identified for the Australasian strewn field.
2.4.5.1 North American Strewn Field This is the oldest strewn field, at about 35 Ma (Gentner et al. 1969a, b; Storzer and Wagner 1969, 1971; Storzer et al. 1973; Glass et al. 1986b). The first North American tektites were known from an area near Bedias, Texas (since 1936), and some rare specimens from Georgia (e.g., Barnes 1963a). Two individual finds were reported to be from Martha's Vineyard and from Cuba (Garlick et al. 1971);
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the first location is doubtful, but the latter probably represents a genuine tektite location (see Koeberl 1988, 1989a, for discussion). The extent of the North American strewn field was defined by findings of microtektites in a number of deep sea sediments (see, e.g., Glass et al. 1973, 1979, 1985; Glass and Zwart 1977). On the basis of stratigraphic, compositional, isotopic, and age data they were identified to be part of the North American tektite field. Other spherules of clinopyroxene composition, which were found in several cores throughout the Caribbean Sea and even the Pacific, were earlier thought to be associated with the North American tektite strewn field, but later shown to belong to a different event (e.g., Glass et al. 1985; D'Hondt et al. 1987; see Sect. 3.3 for more details).
Fig. 2.4.5.1.1. Three-dimensional view of the Chesapeake Bay impact structure crater floor, with crater fill and post-impact sediments removed (computer image courtesy C.W. Poag).
The discovery of tektite fragments associated with microtektites in deep-sea deposits (that are now on land) at Barbados extended the occurrences of "normal" tektites within the strewn field (Glass et al. 1984). Chemical analyses (Koeberl and Glass 1988), isotopic studies (Ngo et al. 1985) and age data (Glass et al. 1986b) showed that the Barbados tektites belong to the North American strewn field. From their Rb-Sr/Sm-Nd isotopic studies, Shaw and Wasserburg (1982)
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concluded - as mentioned before - that the source rocks from which the North American tektites were derived were crustal material that formed very late in the Precambrian (Sm-Nd model age 0.62-0.67 Ga), which excludes most of the Precambrian shield areas of North America, as well as sediments derived from these areas. Microtektites, tektite fragments, and impact debris occur together in relatively thick layers at DSDP Site 612 and ODP Site 904A (e.g., Thein 1987; Glass et al. 1998). The chemical composition of the DSDP 612 and ODP 904 tektites and microtektites is similar to that of other North American tektites, with some differences, e.g., lower Na and higher K contents in the 612 tektites (Koeberl and Glass 1988). Stecher et al. (1989) found that the Rb-Sr/Sm-Nd isotopic compositions of the 612 tektites show a wider scatter than that of the North American tektites. It was also debated if the 612 tektites are in a layer identical in age to that of the other North American microtektites (as proposed mainly by Glass 1989), or if they are in a different layer, which seems highly unlikely, given the chemical similarities. Keller etal. (1983, 1987) suggested that there are least three different Late Eocene impact layers (including the North American tektites), and Miller et al. (1991) additionally maintain that the Site 612 tektites are 0.5-1 Ma older than the other North American tektites and propose 3-4 Late Eocene impacts. However, this has been disputed by Glass (1990) and Wei (1995). Recently Glass and Koeberl (1999a) and Vonhof and Smit (1999) have reported microtektites, probably of North American strewn field association, from ODP Site 689B at Maud Rise, Southern Ocean (near Antarctica) and possibly even in the Indian Ocean (Glass and Koeberl 1999b). These findings would mean that the North American tektite strewn field is much larger than thought before. Over the years, many locations have been suggested as the North American tektite source crater, mainly based on similarity in age. Among the suggestions were, for example, Popigai, Siberia (Dietz 1977); Wanapitei, Canada; Mistastin, Canada; and Bee Bluff, Texas (Wilson and Wilson 1979; King 1979), all of which were later discounted on basis of distance, exact age, isotopic constrains, size, and other criteria (e.g., Storzer and Wagner 1979; Shaw and Wasserburg 1982; Ngo et al. 1985; Koeberl 1989a; Glass 1989; Stecher et al. 1989). More recently, the Montagnais crater, located 200 km southeast of Nova Scotia and the first underwater crater ever discovered (Jansa and Pe-Piper 1987), was considered as a candidate, but neither its age (51.5 Ma; Bottomley and York 1988) nor isotopic data (Stecher et al. 1989) agree with those of the North American tektites. From the distribution of the tektites in the strewn field, Koeberl (1989a) and Glass (1989) suggested that the North American tektite source crater may be located at or near the eastern coast of the North American continent, maybe underwater. This proposal may have been confirmed by the recent discovery of the Chesapeake Bay structure (centered at 37016.5 , N and 76o0.7 , W). It is a complex peakring feature with a diameter of about 85 to 90 krn (Fig. 2.4.5.1.1). The structure is currently buried 300-500 m beneath lower Chesapeake Bay, its surrounding peninsulas, and the adjacent inner continental shelf (Poag et al. 1994; Koeberl et al. 1996c; Poag 1997b; see also Sect. 3.3.1). The structure is partly filled with a unit
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termed the Exmore breccia (Poag et al. 1992), which is mainly composed of autochthonous sedimentary clasts in a sandy matrix, but also containing millimeter- to centimeter-sized basement clasts (Fig. 2.4.5.1.2). An impact origin was confirmed for the Chesapeake Bay structure by Koeberl et al. (1996c), based on the discovery of evidence for shock metamorphism (in granitic clasts within Exmore breccia samples) in the form of shock mosaicism in quartz, and abundant occurrences of shocked quartz, K-feldspar, alkali feldspar, and plagioclase grains.
Fig. 2.4.5.1.2. Drill cores (from the Windmill Point core; see Poag et al. 1994; Koeberl et al. 1996c) showing (left part) the Exmore Breccia unit beneath the Chesapeake Bay impact structure; on the right side are four core sections of the Paleocene Aquia Formation (photo courtesy C.W. Poag).
The age of the structure has been estimated at 35.5 Ma, based on micropaleontological studies of the breccia and correlation with near-by impact deposits (Poag and Aubry 1995). The age, location, and geochemical composition of some basement clasts found within the breccia, which is similar to that of North Americantektites, led Koeberl et al. (1996c) to suggest that it might represent the source crater of the North American tektites. This conclusion also agrees with the Rb-Sr and S m - N d data (Show and Wasserburg 1982; Stecher et al. 1989), which indicated that their source rocks are likely to be derived from the Appalachian orogeny, in agreement with lithologies present beneath Chesapeake Bay.
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I
i
1
i
cm
iiiiiii~%1 iiiiiiiiiiiiiiii!iiiiil
Fig. 2.4.5.2.1. Moldavite tektites (from Besednice, Czech Republic) from the Central European strewn field, a) Assortment of four samples, showing the variety in shapes and the deeply corroded nature of the tektites (in contrast to the much less corroded tektites from the Australasian strewn field; compare Figs. 2.4.1 and 2.4.2). b) Closeup of one moldavite sample (about 3 cm in long dimension) in transmitted light (samples courtesy H. Stehlik).
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2.4.5.2 Central European Strewn Field The first tektites from this strewn field have been described from Bohemia and Moravia (now in the Czech Republic) as early as the 18th Century. They were noted for their green color ("Bouteillensteine" - "bottle stones"). These were the first tektites to be analyzed for chemical composition (by the German chemist M. Klaproth in 1816). "Moldavites" were named after the first place (near the fiver Moldau - which is German for Vltava) they were found: this name has become the most widely used name for this group of tektites (2.4.5.2.1a, b). Within the last two decades, though, moldavites have also been found near Dresden (Germany), and in northern Austria. No microtektites are known from this strewn field. A more detailed account of historical aspects and distribution of the tektites is given by, e.g., Barnes (1963a), O'Keefe (1976), and Koeberl et al. (1988).
Fig. 2.4.5.2.2. Composite aerial view (from the southwest) of the Ries impact crater in southern Germany. The rim of the 24-km-diameter crater, which is the source crater of the Central European tektites, is marked by clouds (photo courtesy Rieskratermuseum N6rdlingen).
The Ries crater in southern Germany was found, within errors of the measurement, to be of the same age (15 Ma) as the moldavites (Staudacher et al. 1982). Studies of the stratigraphy of the crater (see review by H6rz 1982) have shown that different ejecta from the Ries crater are related to a stratigraphic succession of the target rocks. From chemical and isotopic studies, the moldavites were interpreted to be high-speed ejecta derived from the uppermost layers of rock, the so-
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called Upper Freshwater-Molasse unit, but not from any of the deeper stratigraphic units at the Ries crater (see, e.g., Delano and Lindsley 1982; Shaw and Wasserburg 1982; Horn et al. 1985; Delano et al. 1987; Engelhardt et al. 1987).
2.4.5.3 Ivory Coast Strewn Field Ivory Coast tektites were first reported in 1934 from a geographically rather restricted area in the Ivory Coast (Cote d'Ivoire), West Africa. Although some additional specimens have been found later, the total number remains small (a few hundred). Microtektites (Fig. 2.4.5.3.1) were reported from deep-sea sediments of corresponding age from the eastern equatorial Atlantic Ocean west of Africa (e.g., Glass 1969; Gentner et al. 1970; Glass and Zwart 1979; Glass et al. 1991).
Fig. 2.4.5.3.1. Microphotograph of Ivory Coast microtektites from core K9-56 (see Glass et al. 1991), showing the variation in size and shape that is typical for microtektites. Spherical shapes are most common, but teardrops, dumbbells, and fragments are also found. Diameter of image 6.7 mm (photo courtesy B.P. Glass).
The first suggestions that the 10.5 to 11 km diameter Bosumtwi (or Ashanti) crater in Ghana (Fig. 2.4.5.3.2) is the source crater for the Ivory Coast tektites were made in the early 1960s (e.g., Barnes 1961). The Ivory Coast tektites and the Bosumtwi crater have the same age (1.07 Ma; Koeberl et al. 1997b), and there are close similarities between the isotopic and chemical compositions of the tektites
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and crater rocks (e.g., Fleischer and Price 1964; Kolbe et al. 1967; Schnetzler et al. 1966, 1967; Taylor and Epstein 1966; Gentner et al. 1969a, b; Storzer and Wagner 1977; Jones 1985; Koeberl et al. 1997b, 1998b). These observations strongly support a connection between the crater and the tektites. The crater is excavated in 2.1-2.2 Ga old metasediments and metavolcanics of the Birimian Supergroup (e.g., Jones et al. 1981). Koeberl et al. (1998b) found that the target rocks do not show any unambiguous evidence of shock metamorphism, but that distinct impact-characteristic shock effects (PDFs) were identified only in clasts within suevite-derived melt fragments. The compositional range of the target rocks is significantly wider than that of the Ivory Coast tektites, but overlap the tektite compositions. These authors found initial 87Srp6Sr ratios of 0.701 and end values of -17.2 to -25.9%o in the Bosumtwi rocks.
Fig. 2.4.5.3.2. Aerial photograph of the 11-km-diameter Bosumtwi impact structure in Ghana, from the north rim. The central part of the crater is filled by the about 8-km-diameter Lake Bosumtwi, which has a maximum depth of about 80 m (photo courtesy L. Pesonen).
Using mixing calculations, Koeberl et al. (1998b) were able to reproduce the composition of Ivory Coast tektites from a mixture of Bosumtwi country rocks that includes about 70% phyllite-graywacke, 16% granitic dike, and 14% Pepiakese granite. The oxygen isotopic composition of the metasedimentary rocks and granitic dikes (~tSO = 11.3-13.6%o) and the tektites (8'80 = 11.7-12.9%o) agree fairly well. The large variation in Sr and Nd isotopic compositions of the target
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rocks do not allow the unambiguous identification of distinct endmember compositions, but in both a 878r/S6Sr vs. 1/Sr plot and an esr vs. ~d diagram, the tektites plot within the area occupied by the metasedimentary and granitic Bosumtwi crater rocks. These data support the interpretation that the composition of the Ivory Coast tektites is similar to that of rocks exposed at the Bosumtwi impact structure, indicating formation during the same impact event.
2.4.5.4 Australasian Strewn Field For the Australasian field, no crater of the appropriate age is known, although many proposals for possible source craters from all around the world were made and later discounted (e.g., Weihaupt 1976; Bentley 1979; Dietz 1977; Glass 1979; Koeberl and Fredriksson 1986; Shaw and Wasserburg 1982; Storzer and Wagner 1979; Hartung and Rivolo 1979; Ford 1988). In contrast, Barnes (e.g., Barnes and Pitakpaivan 1962; Barnes 1989, 1990) suggested that the Australasian tektites have originated from an impact of a "diffuse object such as a comet", obviating the need for a distinct large source crater. In a similar vein, Wasson (1991) suggested that the tektites originated from a multitude of small craters scattered over all of Indochina. There are numerous problems with this model (see Blum et al. 1992; Koeberl 1992a; and Koeberl 1994b for detailed discussions). Bunopas et al. (1999) suggested that there is evidence for large-scale forest fires in Thailand that are coeval with the tektite formation event. Most workers agree that a single large impact crater is a much more plausible source crater of the Australasian tektites. Recently, Howard et al. (2000) reported on the possible presence of shocked quartz from a layer immediately above a tektite-bearing horizon in Thailand. If confirmed, this observation would support the single impact hypothesis. Fission-track data suggested that australites may have a slightly different age than other Australasian tektites (Storzer and Wagner 1980a, b), but Glass (1986) found no evidence for a second, older (0.8-0.9 Ma), microtektite-bearing layer in deep-sea sediments. Bollinger (1993) and Izett and Obradovich (1992) found no age difference between australites and other Australasian tektites in their detailed Ar-Ar studies. Their best-fit age is 0.77 + 0.02 Ma, which agrees well with the revised age for the Brunhes-Matuyama geomagnetic polarity reversal with which the Australasian microtektite layer is closely associated; however, the microtektite layer does not directly coincide with the Brunhes-Matuyama reversal, but the Australasian microtektites were deposited about 15,000 years prior to the geomagnetic reversal (Schneider et al. 1992). The geographic distribution of Australasian tektites and microtektites is not homogeneous: there are radial and concentric patterns, and zones that do not contain microtektite-bearing deep sea cores (e.g., Stauffer 1978; Schnetzler 1992; Glass and Wu 1993). From an analysis of the radial distribution patterns, Stauffer (1978) suggested a crater that may be concealed beneath alluvial deposits of the lower Mekong Valley area. Schnetzler et al. (1988, 1999) suggested a possible oft-shore impact location (about 175 km to the east of the Vietnam seashore) from
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satellite gravity data. Hartung and Koebefl (1994) proposed that the Lake Tonle Sap (about 100 km long and up to 35 km wide) in Cambodia was created by the Australasian tektite event. The dimensions are probably minimum values as the structure is almost completely filled with alluvium. The location of Tonle Sap is in agreement with chemical and isotopic (Rb-Sr/Sm-Nd) data for tektites, but more detailed studies are necessary. A first expedition to the Tonle Sap area has identified some possible source rocks, but no proof for impact has yet been found (partly due to the inaccessibility of the area). The quantity of both impact debris and microtektites in cores all over the Australasian strewn field increases towards Indochina (Glass and Wu 1993; Glass and Pizzuto 1994), which supports the locations proposed by Stauffer (1978) and Hartung and Koeberl (1994). The same conclusion (i.e., a possible single source crater in Cambodia, about 100 km in diameter) was also obtained in a recent study of microtektite distributions by Lee and Wei (2000). However, the Australasian tektite source crater remains, for the time being, elusive.
2.4.6 Tektite Formation: Facts and Open Questions Our current understanding of the tektite-producing impact processes is still riddled with open questions. An attempt to present physical (or mathematical) models of a tektite-forming impact may not be successful at this time, because only educated guesses, but no detailed models, exist (Melosh 1989, 1998). First, it is useful to review processes that we know to have operated during tektite formation. Volatilization. There has been a debate about the extent of volatilization and vapor fractionation that have affected tektites, ranging from very important (e.g., Walter and Carron 1964; Walter 1967; Walter and Clayton 1967; Ridenour 1986) to minimal (e.g., Molini-Vesko et al. 1982; Koeberl 1992a; Chaussidon and Koeberl 1995). Most chemical variations can be explained by a variation in source rock composition. There is little doubt, however, that the most volatile elements (e.g., the halogens, Cu, Zn, Ga, As, Se, Pb) were volatilized from the source rocks upon melting because the Muong Nong-type tektites, suspected to have experienced the lowest temperatures of all tektites, contain higher abundances of these elements than the splash-form tektites (Koeberl 1992a). Water in Tektites. Tektites are, in general, very poor in water, with contents ranging from about 0.002 to 0.02 wt.% (20-200 ppm); impact glasses contain up to about 0.06 wt.% (600 ppm) water (see, e.g., Gilchrist et al. 1967; Engelhardt et al. 1987; Koeberl and Beran 1988; Beran and Koeberl 1997). The low water content is typical for impact glasses and can be used as convincing evidence for an origin by impact, as has recently been demonstrated by Koeberl (1992b) for the glasses from the Haitian K/T-boundary. It also easily distinguishes tektites from lunar materials, which have at least six orders of magnitude less water than tektites (e.g., Taylor 1982). Contrary to earlier belief, experimental evidence shows that it is possible to drive water out of parent sediments (containing up to several percent water) during the short time available for the tektite production (e.g., Glass et al.
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1986a, 1988). In preliminary calculations on diffusion coefficients governing the water depletions in tektites, Vickery and Browning (1991) conclude that the calculated depletions are more than sufficient to account for the observed water contents in tektites. More recently, Melosh (1998) found that when silicates are shocked to 100 GPa, they almost instantaneously reach temperatures in excess of 50,000 K. Pressure release first leads to a supercritical silicate fluid and, once pressures drop below about 0.1 GPa, appearance of both a liquid and a vapor phase. Temperatures at this time are still around 5000 to 10,000 K and may remain in this range for several tens of seconds. Silicate viscosities at these temperatures are very low (about five orders of magnitude less than that of liquid water), and it is very likely that at these conditions water and other volatiles, including the noble gases, are rapidly lost. Gases in Tektites. M~ller and Gentner (1968) found that bubbles in tektites contain residues of the terrestrial atmosphere at low pressures. Jessberger and Gentner (1972) measured the gas content and composition in bubbles in Muong Nong-type tektites and found that the N2/Ar ratio, as well as the isotopic ratios of 4°Ar/36Ar,36ArfSAr, 82Kr/84Kr, 129Xe/132Xe,84Kr/132Xe,and others, agree well with the respective atmospheric ratios, providing further evidence for an origin of tektites within the terrestrial atmosphere. Matsuda et al. (1989) and Matsubara et al. (1991) showed that the ratios of rare gases in impact glasses and tektites are consistent with those of the terrestrial atmosphere, and that, because of its higher mobility, during the long terrestrial residence times, Ne has predominantly diffused into the glass (Matsubara and Matsuda 1991). Tektites have low contents of dissolved heavy noble gases (Matsuda et al. 1993; Palma et al. 1997), and calculations show that, in order to explain the noble gas contents, tektite glass must have solidified at low ambient pressure, equivalent to a height of about 40 km in the atmosphere (Matsuda et al. 1993). Matsuda et al. (1996) studied a philippinite with a large (5 cm 3) bubble. The total gas pressure in this bubble was very low about 10.4 arm. The gas in the bubble contained higher He and Ne abundances, compared to the other noble gases, and unusually high 2°Ne/22Ne and 2~Ne/22Ne ratios, which were interpreted as the result of very fast non-steady state diffusion in the early stages of tektite formation. Furthermore, Matsuda et al. (1993) showed that Muong Nong-type tektites contain higher abundances of the heavy noble gases than splash-form tektites (closer to values observed in "normal" impact glasses), and that the isotopic composition of Ne in vesicles in Muong Nong-type tektites is practically identical to that of the terrestrial atmosphere. The "Age P a r a d o x " . The so-called age paradox (i.e., the observation that the stratigraphic age of many Australasian tektites found on land was reported to be much younger than their radiogenic age), has been discussed in detail in previous publications (e.g., Koeberl 1994b; Taylor and Koeberl 1994; Taylor 1999). In short, some authors have used this apparent discrepancy to argue against a relationship between microtektites and tektites, and that tektites only fell around 7000-24,000 years ago (e.g., Lovering et al. 1972; Chalmers et al. t976). On the other hand, Gentner et al. (1970), and others, showed that microtektites found in the Australasian tektite strewn field have the same fission-track age of 0.7 Ma,
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which is in perfect agreement with the stratigraphic age of Australasian microtektites (e.g., Glass 1978; Glass et al. 1979). Glass and Wu (1992) have not found any indication for a younger event in deep-sea sediments less than 20,000 years old from 46 deep-sea drill cores. Chemical, isotopic, and age data confirm that microtektites and tektites have been produced in the same event. The discovery of shocked minerals and impact glasses together with microtektites in several deep sea sediments of the Australasian and North American strewn fields (e.g., Glass and Wu 1993) confirm the link of tektite production to impact events. Fudali (1993) showed that the proposed stratigraphic age of 5000-15,000 years for some australites is demonstrably incorrect. Shoemaker and Uhlherr (1999) found tektites weathering out of strata at Port Campbell (Victoria, Australia) that agree in age with the radiometric age determinations for tektites, demonstrating that the young stratigraphic age for tektites is only apparent at the result of reworking from older strata. Meteoritic Component in Tektites. The geochemistry of tektites from all strewn fields is indistinguishable from that of the recent terrestrial upper crust. Meteoritic components (see Sect. 1.8) in tektites are very low or below detection limit (e.g., Morgan et al. 1975; Morgan 1978; Palme et al. 1978, 1979). A few philippinites contained some Ni-rich iron spherules, but this could have been due to in-situ reduction of target rocks (Ganapathy and Latimer 1983). The Ivory Coast tektites are the only ones that have a detectable extraterrestrial component (Koeberl and Shirey 1993). Morgan (1978) found only one HMg australite (out of six analyzed) that was slightly enriched in platinum-group elements. Koeberl et al. (1999a) found a significant meteoritic signature in bottle-green microtektites. Impactoclastic layers associated with tektite and microtektites have been only slightly more rewarding. Asaro et al. (1982) and Ganapathy (1982) reported enrichments of Ir in drill-cores from the North American strewn field at the same position where clinopyroxene sphemles (but not microtektites; Keller et al. 1987) had been found, but no meteoritic component was found in the tektites; however, we now know that the Ir is associated with the Late Eocene clinopyroxene layer (cf. Glass and Burns 1987; Montanari 1990; Montanari et al. 1993). Schmidt et al. (1993) and Koebed (1993a) found evidence for a minor Ir anomaly in deep-sea sediments associated with the Australasian microtektite-bearing layer in ODP core 758B (east of Malaysia, in the southern part of the Bay of Bengal). The low meteoritic contents indicate that no intimate mixing between projectile and target seems to have taken place during tektite formation. Cosmogenic Radionuclides and Target Stratigraphy. The study of cosmogenic radionuclides provides evidence on the nature of the sedimentary precursor and the target stratigraphy. Pal et al. (1982) demonstrated that the '°Be content of Australasian tektites cannot have originated from direct irradiation with cosmic rays in space or on Earth, but can only have been introduced from sediments that have absorbed 1°Be that was produced in the terrestrial atmosphere. This conclusion was supported by several additional studies (e.g., Yiou et al. 1984; Englert et al. 1984). The concentration of Z6A1is of crucial importance: if tektites were ever exposed to cosmic radiation in space to produce the observed ~°Be concentra-
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tion, then the 26A1]1°Beratio must be between 2.7 and 5.4, depending on the details of the irradiation. Middleton and Klein (1987) found that the 26A1concentration in tektites is so low that they were able to measure its concentration in only one sample, giving a Z6A1/l°Beratio of about 0.07. Ivory Coast tektites and impact glasses (e.g., Aoulelloul) were also found to contain 1°Be (Tera et al. 1983a, b; Raisbeck et al. 1988). Cosmogenic radionuclides can also help in understanding of the target stratigraphy. The distribution of 1°Be in the environment is a strict function of the depth from the surface. Pavic et al. (1983) and Valette-Silver et al. (1983) demonstrated that most ~°Be is concentrated in the upper 20 m of soils and sediments. This limit may be variable as a function of different rock types, rainfall rate, and porosity, but probably by less than a factor of 10. Blum et al. (1992) have calculated that mixing of a 200 m column of bedrock into the surficial cover that contains the 1°Be explains the '°Be concentrations observed in Australasian tektites. The absolute concentrations of ~°Be in the various types of Australasian tektites allow another important conclusion. The '°Be concentrations in australites are higher than those in indochinites and philippinites, which in turn are higher than those in Muong Nong-type tektites, with average contents in australites, splash-form indochinites, and Muong Nong-type indochinites being 150.106, 100.106, and 57-106 atoms '°Be/g, respectively (Tera et al. 1983a, b; Pal et al. 1982; Raisbeck et al. 1988; Aggrey et al. 1998). For these data it can be concluded that australites (which experienced the highest temperatures and are the most distant ejecta) originated from close to or at the surface, whereas the Muong Nong-type tektites originated from a somewhat deeper unit, in agreement with impact mechanics and compositional data. Open Questions. Despite the identification of three tektite source craters (out of four), the exact target rocks from which tektites have been produced are not known. There are numerous reasons for this: e.g., during the impact, melting of a variety of target rocks occurred; we still do not understand the exact physical and chemical processes which may alter the chemical composition during impact (i.e., unspecific fractionation); impact mixing is a non-equilibrium and heterogeneous process; also, tektites are most probably produced in the earliest stages of impact, which are poorly understood. Jakes et al. (1991, 1992) and Melosh (1998) have discussed the importance of superheating, and that superheated melts are reduced. This model may very well be valid, although we do not know in which state the tektite material is after impact melting, or, what the size distribution of the melt droplets is. Thermal data for tektites are not abundant (Wilding et al. 1996). Engelhardt et al. (1987) suggested that the tektite material is completely vaporized to a plasma state, and then recondensed in the form of coalescing droplets. It seems, however, that in such a model the relatively close compositional similarity between the tektites and their source rocks would be lost; also, the presence of lechatelierite particles in tektites cannot be explained by this model. It may also be important that tektites are more reduced in composition compared to impact glasses (e.g., Fudali et al. 1987; Yakovlev et al. 1993).
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The formation of tektites, in which up to 1 0 9 t of glassy material is distributed over distances of up to 12,000 km (or about 800 km from the proposed source region, in the case of the Australasian tektites), must require distinct conditions, because otherwise more than just four tektite strewn fields would be known on Earth, considering the number of craters known. Maybe low angle impact is important because of the asymmetric distribution of tektites within a strewn field. This is true for all four cases: where craters are known to be associated with tektite fields, the craters are never in the center of the strewn field. Tektites and microtektites are not uniformly distributed within the strewn fields, but may follow some kind of ray-like pattern (similar to rays around lunar craters, but asymmetric); this may be related to the formation process. Tektite production has to occur before the main excavation phase of the crater formation has started. Numerous arguments have been presented here that show that tektites had to originate from target rock layers close to the surface. For example, it is otherwise not possible to explain their 1°Be content. The finding that bottle-green microtektites contain a significant meteoritic component indicates that these microtektites may have formed in the earliest phase of tektite formation. The quest to deduce the exact process of tektite formation, if by bow-shock melting (cf. Bohor and Koeberl 1996; Scott 1999), melting induced by an incandescent atmosphere (Wasson 1991; Wasson and Moore 1998), or a direct impact process, and the ejection mechanism (e.g., jetting - see Vickery 1993, for a discussion; or by ballistic shadowing - see Sugita et al. 1998), will provide material for much more research in the future.
2.5 Other Impact Glasses: Relation to Source Craters Glasses have been found at several impact structures around the world, such as at the Aouelloul (Mauritania), Darwin (Tasmania, Australia), Henbury (Australia), Lonar (India), Wabar (Saudi Arabia), or Zhamanshin (Kazakhstan) craters (e.g., Taylor 1966; Kieffer et al. 1976b; Morgan 1978; Taylor and McLennan 1979; Koeberl and Fredriksson 1986; Koeberl and Storzer 1988; Meisel et al. 1990; Attrep et al. 1991a; Garvin and Schnetzler 1994; Koeberl et al. 1998a). All of these have in common that the craters are relatively young (ranging from about 6000 years or less for Wabar to 3.1 million years for Aouelloul), that the glass is found directly at the crater (less than one crater radius from the rim), and that the glasses provide the only confirming evidence that the host craters are of impact origin. For example, Aouelloul impact glasses (Fig. 2.5.1) are water-poor, have abundant schlieren of different chemical composition, partly digested quartz and feldspar grains, and contain lechatelierite and baddeleyite. The composition of the glass is similar to that of the sandstone in which the crater is exposed, but some siderophile elements are enriched in the glass. Koeberl et al. (1998a) performed Re-Os isotope studies (cf. Sect. 1.8.3) of the target sandstone and the impact glass and demonstrated the presence of a distinct extraterrestrial component in the glass. Whereas studies of such impact glasses are interesting and provide important
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information about cratering processes, they are not distal ejecta and, therefore, only of peripheral interest here. It should be emphasized that the same applies also to impact glasses from the Zhamanshin crater (zhamanshinites and irghizites), which are often erroneously called "tektites".
Fig. 2.5.1. Fragment of dark impact glass at the Aouelloul crater in Mauritania, on the south flank of the crater rim, about 100 m outside the rim. The glass provides the only physical evidence exposed on the surface that this structure is an impact crater.
Chapman and Scheiber (1969), in their detailed study of the composition of Australasian tektites, identified nine australite samples (from several locations in Australia) that have much higher Na and lower K contents than any other australites and were, thus, termed HNa/K australites (because they have a high Na/K ratio). Table 2.5.1 gives data for the major elements and selected trace elements for the HNa/K tektites in comparison with average indochinites. Fleischer et al. (1969) found that the age of samples from this australite subgroup is distinct from that of the other australites (they obtained ages around 4 Ma). Whereas the oxygen isotopic composition of these tektites is not unusual (Taylor and Epstein 1969), they do have distinct Sr (Compston and Chapman 1969), Nd and B isotopic and trace element compositions (Table 2.5.1; Koeberl et al. 2000b) that set them apart from other Australasian tektites. New age determinations by fission track, K/Ar, and A r - A r dating indicate ages around 10 Ma (Storzer 1985; Storzer and MtillerSohnius 1986; Koeberl et al. 2000b), confirming that these nine tektite samples do represent a different impact event, but the source crater is, so far, unknown. Other glasses of obvious impact origin, but unknown source include the socalled urengoites, a group of three samples, and the single (unrelated) south Ural Glass, which were analyzed by Deutsch et al. (1997). The urengoites, tektite-like objects from western Siberia, have high SiO 2 contents of 89 to 96 wt.%, crustal REE patterns as well as Sr and Nd isotope values, and ages of about 23 Ma. No
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source crater has yet been identified. A few samples of tektite-like glass of unusual composition were found among the ruins of the Mayan town of Tikal, Guatemala (Hildebrand et al. 1994). This glass is unrelated in age and composition to North American tektites. At present, the source of the glass is unknown.
Table 2.5.1. Composition of HNa/K australites in comparison to "normal" indochinites. HNa/K australites (range) SiO2 TiO2 A1203 FeO MnO MgO CaO Na20 K20
Indochinite (average)
61.7-64.0 0.49-0.61 15.7-16.4 5.59-6.88 0.09-0.12 3.44-4.43 4.49-6.27 2.71-3.98 0.44-1.12
72.7 0.78 13.4 4.85 0.08 2.14 1.98 1.05 2.62
Sc Cr Co Ni Rb Sr Zr Th U
10.5-14.5 205-385 45.3-68 650-875 29.6-39.3 435-550 140-168 3.62-5.31 0.52-0.88
10.5 63 11 19 130 90 252 14.0 2.07
Esr (%0) ENd(%0) Age (Ma)
-12.2 +4.7 10
+200 -11.5
0.78
Major element data in wt.%, trace elements in ppm. All Fe as FeO. Indochinite data from Taylor and McLennan (1979) and Blum et al. (1992); HNa/K data from Chapman and Scheiber (1969) and Koeberl et al. (2000b).
2.5.1 Libyan Desert Glass Libyan Desert Glass (LDG) is an enigmatic natural glass found in an area of about 6500 km 2 between sand dunes of the southwestern corner of the Great Sand Sea in western Egypt, near the Libyan border. The glass occurs as centimeter- to decimeter-sized irregular and strongly wind-eroded pieces. The total quantity of the glass present has been estimated at 1.4.109 grams, with a much larger original
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mass assumed (Barnes and Underwood 1976; Diemer 1997). In terms of chemical composition, LDG is very silica-rich and has low abundances of most major oxides (Table 2.5.1.1). The age of the LDG was determined by K-Ar and fissiontrack methods. While it is possible to calculate a K-Ar ages for LDG (58.3 -+ 16.4 Ma; Matsubara et al. 1991), these values suffer from the very low K content of the glass, and other methodological problems (Horn et al. 1997). Better suited for an age determination of the LDG is the fission-track method, which gave ages ranging from 28.5_+2.3Ma (Storzer and Wagner 1971) to 29.4 _+0.5 Ma (plateau age; Storzer and Wagner 1977), which was recently confirmed (28.5 _+0.8 Ma) by Bigazzi and de Michele (1996); see also Horn et al. (1997). The origin of LDG has been the subject of much debate since it was discovered early in the 20th century (cf. Clayton and Spencer 1934; Weeks et al. 1984; Diemer 1997). Many workers were of the opinion that LDG is an impact glass (e.g., Kleinmann 1969; Jessberger and Gentner 1972; Barnes and Underwood 1976; Fudali 1981), but were deterred by the lack of a suitable impact crater. To avoid this problem, Seebaugh and Strauss (1984) suggested that the glass formed in a cometary collision, where shock-melting occurred without crater formation. Various other suggestions for the origin of LDG were made (e.g., a sol-gel process, or a sedimentary origin), but none of these suggestions were confirmed by any evidence. Most researchers have now accepted the geochemical and geological evidence for an impact origin of LDG; see, e.g., Diemer (1997); Storzer and Koeberl (1991); Koeberl (1997b); Murali et al. (1989, 1997); Rocchia et al. (1996a, 1997); Abate et al. (1999). Evidence for an impact origin includes the presence of schlieren and partly digested mineral phases, such as lechatelierite (a high temperature melt of quartz); baddeleyite, a high temperature break-down product of zircon (Kleinmann 1969; Storzer and Koeberl 1991; Horn et al. 1997); and the likely existence of a meteoritic component (see below). Storzer and Koeberl (1991) suggested from their Zr/U and REE data that none of the sands or sandstones from various sources are good candidates to be the sole precursors of LDG. Compositional data for surface sands (Koeberl 1997b) show significant differences to the average LDG composition. Some admixture of monazite and/or apatite (e.g., from some type of sediment) seems likely to explain both the excess U and the REE patterns, although a better correlation is found with rocks from the BP and Oasis impact structures (see below). More importantly, though, is the existence of a meteoritic component in LDG (Murali et al. 1989; Rocchia et al. 1996a; Koeberl 1997b). These authors have found that the contents of siderophile elements, such as Co, Ni, and Ir, are significantly enriched in some rare dark bands that occur in some LDG samples (Figs. 2.5.1.1 and 2.5.1.2). Koeberl (1997b) studied such dark bands and found that the contents of Fe, Mg, and Ni are high in the dark zones and low in the "normal" LDG. This co-variation can only be explained by a common source for those elements. Together with the observations of Murali et al. (1989), Rocchia et al. (1996a), and Koeberl (1997b) of high Ir contents in the clark zones, these data are
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only consistent with the presence of a meteoritic component. This is also in agreement with Os isotopic data of dark bands in LDG (C. Koeberl; unpublished data). The presence of a meteoritic component in LDG samples makes the Tunguska-like airburst hypothesis advanced by Wasson and Moore (1998) rather unlikely, as an extraterrestrial component in the glass would have to be the result of actual physical contact between the impactor and the target rocks.
Table 2.5.1.1. Major and selected trace composition of Libyan Desert Glass. Average SiO2 TiO2 A1203 FeO MgO CaO Na20 K20 P205 Sc Cr Mn Co Ni Rb Sr Zr La Th U
98.4 _+0 . 8 9 0.12 _+0 . 0 6 1.19 _ 0 . 6 9 0.12 + 0 . 0 9 0.011 _+0.002 0.01 _+0 . 0 0 5 0.005 _+0.001 0.009 _+0.003 0.01 _+0 . 0 0 5 0.79 + 0 . 4 2 5.74 + 2.64 13.2 _+3.62 0.26 _+0 . 1 4 2.5 + 2.0 0.46 _+0 . 1 2 24 + 7 196 + 47 6.91 + 1 . 9 9 2.59 _+0.83 0.96 _+0 . 2 8
Range 96.6-99.3 0.05-0.24 0.54-2.58 0.05-0.39 0.008-0.015 0.01-0.02 0.003-0.007 0.006-0.014 0.005-0.012 0.26-1.66 1.8-10.4 7.6-19.1 0.11~).58 1-8 0.28-0.68 17-37 105-270 3.52-11.1 1.0-3.84 0.41-1.45
Major element data in wt.%, trace element data in ppm. Data from Koeberl (1997b).
The geographic proximity of the LDG site to the BP and Oasis impact structures (French et al. 1974; see Koeberl 1994a for a review) has previously led to speculation that one of these two structures might be the LDG source. Diemer (1997) suggested that the BP and Oasis structures, which occur in the Nubian sandstone, of Early Cretaceous age, are older than the LDG. However, recent geochemical investigations related to the origin of Libyan Desert Glass (Barrat et al. 1997; Horn et al. 1997; Koeberl 1997b; Abate et al. 1999) indicated that the target rocks of the BP and Oasis structures are good candidates for the source material of LDG. Abate et al. (1999) conducted petrographic studies and, for the first time, major element, trace element, and isotopic analyses of rocks from the
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BP and Oasis impact structures, for comparison of their geochemical characteristics with those of LDG.
i (/i ¸ !i!iiiiii;
Fig. 2.5.1.1. Libyan Desert Glass sample (about 2 mm thick slice) in transmitted light, showing dark streaks, which contain evidence for an extraterrestrial component. Such dark bands are very rare.
Abate et al. (1999) found that most of the target rocks at both structures have somewhat lower SiO 2 contents than LDG, but this distinction becomes less important when the composition of the sandstones is recalculated to a water-free basis. As for the major elements, there is a good correlation between the trace element compositions of samples from the target rocks of BP and Oasis structures and samples of LDG, but the refractory trace element content of the L D G is generally somewhat higher than that of the target rocks of the two Libyan craters. Rare earth elements (REE) from the BP and Oasis impact structures and from L D G have similar abundances and display a similar chondrite-normalized pattern. The isotopic ratios of Nd and Sr for samples of the two structures and for the L D G are in a simil0r range. They are characterized by negative end values and positive esr values, which are characteristic of upper continental crustal rocks. In an eN, vs.
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esr diagram, L D G values plot within the field defined by the BP and Oasis rocks, and in a 1/Sr vs. esr plot L D G is also within the range defined by BP and Oasis target rocks.
Fig. 2.5.1.2. Photograph of a polished "thick section" (about 0.5 mm thick) of a Libyan Desert Glass sample with dark streaks. Elongated bubbles are evidence for glass flow. Sample wide dimension about 10 mm.
All these petrographic, geochemical and isotopic data suggest that rocks found at the BP and/or Oasis structures could represent the parent material for LDG, but without further age information on the two impact structures it is not possible to unambiguously conclude that the BP or Oasis structures are the source craters for the LDG. All this puts Libyan Desert Glass in a unique place: they are unlike tektites in many ways (e.g., they appear to occur only in a geographically restricted area, not an extended strewn field; they have higher water contents than tektites; some have significant meteoritic components), and they are also unlike lithic distal ejecta in that they are not associated with any shocked minerals or rock fragments. If they really originated from the BP or Oasis structures (maybe in an oblique impact?), they would have to be classified as distal ejecta - but so far these glasses remain unique in the geological record.
3 Important Distal Ejecta Layers and Their Source Craters
3.1 General In this chapter we describe some key characteristics of the most important distal ejecta layers (e.g., the K/T boundary layer and the Late Eocene layers) and discuss their source craters. We will also discuss some other, less well established, possible impactoclastic layers, and mention some cases where not enough information is yet available to decide if there is an impact connection or not. This information sets the stage for a detailed description of the evidence for impact in the Umbria-Marche Sequence, which is given in Chaps. 4 and 5. The definition of distal ejecta was given in Sect. 2.1 and their use as impact markers in general was discussed in Sect. 2.2.
3.2.
The K/T Boundary and Chicxulub The K/T boundary may not be the first distal ejecta layer that was investigated in detail (microtektite-bearing layers were discovered in the late 1960s; see Sect. 2.4), but it is by far the most important one (see Sect. 2.3), and probably the best studied one (cf. Ryder 1996). The story of the discovery of the K/T boundary layer at Gubbio, Italy, and the subsequent recognition that it is impact-derived, is best told by Atvarez (1997) (see Sect. 5.7 for details and field descriptions). A typical K/T boundary layer has a striking and distinct appearance in the field, and can easily be recognized and identified: there is distinct break in lithology, with a thin (usually up to 1 or 2 cm thick) layer commonly composed of clay or claystone. Good descriptions of field relations are given, for example, by Izett (1990) and Smit (1999), and references therein. Smit (1999) provides a definition of what constitutes the K/T boundary: The Global Stratotype Section and Point (GSSP) of the K/T boundary is at E1 Kef in Tunisia, where a 2 mm thick ejecta layer overlies Maastrichtian calcareous marls. Directly above the thin ejecta layer
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follows a 25 cm thick, fossil-poor, clay layer. The GSSP is placed directly below the ejecta layer, marking the end of the Cretaceous. The ejecta layer contains shocked quartz, Ni-rich spinel, and high PGE abundances. A similar definition can be used for other K/T boundary locations.
Fig. 3.2.1. K/T boundary layer at the Clear Creek North site, Raton Pass, Colorado, near the 1-25 freeway. Scale bar on bottom is about 16 cm wide. This location represents a terrestrial site, in contrast to the marine sites discussed in Sect. 5.7. The boundary horizon is made up of two layers. The lower one is a light gray layer of kaolinite, about 2 cm thick, which is thought to have formed by alteration of glassy spherules. This is overlain by a thinner, laminated brownish "fireball" layer, which, in turn, is overlain by Tertiary coal, reflecting the swamp environment in which the material was deposited (photo courtesy B.F. Bohor).
The discussion of paleontological observations from different K/T boundary sites is mostly beyond the scope of this chapter. This is also the topic on which there is probably the largest variety of opinions, and it would not be possible to do justice to this subject in a short chapter. However, as far as Italian sites are concerned, the paleontological data are reviewed in Sect. 5.7. For other locations and a general discussion of paleontological aspects of the K/T boundary, the reader is referred to papers in Sharpton and Ward (1990), Ryder et al. (1996) and to the recent review of Smit (1999), and references therein. Paleobotanic studies provide also important data in terms of defining how severely the environmental changes induced by the K/T event affected numerous plant species (see, e.g., Tschudy et al. 1984; Spicer 1989). An interesting (but not undisputed) hypothesis was put for-
103
ward by Wolfe (1991), who interpreted the paleobotanical data to indicate that the impact event occurred in June.
Fig. 3.2.2. Goyazite spherules in the lower layer of the K/T boundary at Teapot Dome, Wyoming, USA. The (mostly hollow) spherules are up to about 1 mm in diameter (white scale bar on bottom left is 1 mm wide) and have probably formed by alteration of originally glassy spherules (SEM photograph courtesy B.F. Bohor).
It should be noted that in undisturbed terrestrial K/T boundary locations (e.g., in the Western Interior of North America), the layer is up to 3 cm thick and has a dual nature (Fig. 3.2.1), whereas in most marine sections it does not display a dual-layered nature. At these sites, nannoplankton extinctions occur at the base of the clay layer (within the 29R magnetochron). At the Western Interior locations (Bohor et al. 1987b; Bohor 1990; Izett 1990), the lower layer is mainly of kaolinitic composition with some smectite; it contains hollow spheres up to 1 mm in diameter, which are most often also composed of (and filled by) kaolinite, but at some sites (e.g., in Wyoming) they are composed of goyazite (a hydrous aluminophosphate; an alteration product) and are easily discernable (Fig. 3.2.2). Bohor and Glass (1995) provide a detailed description of the formation and alteration of these spherules. The upper (thinner) layer is commonly laminated and consists of smectite and kaolinite clay with variable amounts of organic matter, giving it a dark gray to black appearance (Bohor 1990). Most of the shocked minerals and the siderophile element anomaly (see below) is restricted to the upper layer; it has been called the "fireball" layer (e.g., Bohor 1990). Shoemaker and Izett (1992) thought that the dual nature of the boundary layer may be the result of multiple impacts at the end of the Cretaceous, but that was at a time when the Manson impact structure in Iowa was still considered to be of K/T boundary age (see
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Sect. 3.4). Despite related suggestions (Koutsoukos 1998), no subsequent evidence to support this suggestion has been found. The composition and internal structure of the K/T boundary layer varies with distance from the source and depositional environment, as described in detail by Smit (1999) in a recent review. However, Smit (1999) unfortunately confuses the issue somewhat by using inappropriate nomenclature: he calls K/T ejecta at <2500 km from the source crater "proximal", those that are 2500 to 4000 km "intermediate", and those at >7000km distance "distal". As described in Chap. 2.1, the definition of proximal and distal ejecta (which existed long before KfF boundary studies were made) is based on a changeover distance of 5 crater radii. Assuming a radius of about 100km for the Chicxulub crater (see Sect. 3.2.2), all sites >500 km from the crater rim should be called "distal"; for further distinction between sites it would be better to use terms in accordance with their proper definition.
3,2.1 Evidence for Impact at the K/T boundary Following the brief review of the appearance of the K/T boundary layer and its geographical variation, it is pertinent to summarize the most important arguments in favor of an impact origin; however, space limitations prevent a detailed discussion of these arguments (see, e.g., the reviews of Kring 1993 and Koeberl 1996, and papers in Silver and Schultz 1982; Sharpton and Ward 1990; Dressler et al. 1994; Ryder et al. 1996; Dressler and Sharpton 1999). For an explanation of the significance of the evidence, see the various sections in Chap. 1. In this section, we first discuss the origin of the rocks that mark the K/T boundary, whereas the link with the Chicxulub structure in Mexico is addressed in Sect. 3.2.2. Despite some claims to the contrary, the K/T boundary provides several independent lines of evidence in favor of the conclusion that an impact event was responsible for the end of the Cretaceous. In the following sections, we describe the observations that are indicative of an impact event 65 Ma ago.
3.2.1.1 PGE Enrichments The first physical evidence pointing to a contribution of extraterrestrial material that was discovered was the presence of unusually high PGE abundances in K/T boundary clay in Italy (Alvarez et al. 1980) and other locations around the world (e.g., Smit and Hertogen 1980; Ganapathy 1980; Kyte et al. 1980); this point has been made repeatedly in Chaps. 1 and 2 and is also discussed in more detail in Sect. 5.7. Iridium and other PGEs were found to be enriched in these K/T boundary clay layers by up to four orders of magnitude compared to average terrestrial crustal abundances. Early in the discussion about the origin of the Ir enrichments, terrestrial sources were suggested as possible causes for these enrichments. For
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example, some volcanoes were found to emit aerosols that are enriched in Ir and other siderophile elements (e.g., Zoller et al. 1983; Koeberl 1989b; Toutain and Meyer 1989), but in none of these cases were the interelement ratios (see next paragraph) similar to those observed at unaltered K/T boundary locations. Such models also fail to explain the overall amount of PGEs found worldwide at the K/T boundary (see, e.g., Kring 1993, for a more detailed discussion). See Sect. 5.7 for a discussion of Ir abundance profiles across typical K/T boundary sections, showing the significant Ir enrichment at the boundary. There is a variation in the absolute amount of Ir found at K/T boundary locations around the world. Values quoted by various authors range from a few hundred ppt (ppt = 10-~zg/g) to a few hundred ppb. However, direct comparison of the data is very difficult, as the results critically depend on which type of sample was analyzed, and how the sample was treated. For example, Eugster et al. (1985) give Ir data for a Stevns Klint K/T boundary sample without treatment (4.6 ppb) and for one that was treated with acids (33 ppb). The absolute value depends in either case on how effectively only the fireball layer was collected, and on how much other material was incorporated in a bulk sample. At some locations (especially those that are close to the impact site, e.g., Gulf of Mexico), the K/T boundary layers are fairly thick and, therefore, the Ir abundance in a bulk sample can be rather low. For example, Rocchia et al. (1996b) found 0.7 ppb Ir in K/T boundary samples from ODP Hole 536 in the Gulf of Mexico. A better measure for the Ir distribution would be the fluence of Ir, which at ODP 536 is 55 ng/cm2 (Rocchia et al. 1996b); this is on the order as the global average for K/T boundary sites. Kyte et al. (1996) found an Ir fluence of about 90 ng/cm2 from K/T boundary samples over most of the Pacific plate.
3.2.1.2 PGE Abundance Patterns; K/T boundary Meteorite? It was found that the interelement ratios of the PGEs in the K/T boundary clays are very similar to the values observed in chondritic meteorites (e.g., Alvarez et al. 1980; Ganapathy 1980; Kyte et al. 1980; Smit and Hertogen 1980; Palme 1982; Tredoux et al. 1989a). Terrestrial sources do not easily explain cosmic interelement ratios. Typical siderophile element data (including PGE data) for two K/T boundary locations are given in Table 3.2.1.2.1. These data, as well as those in the literature cited above, show that redistribution of the PGEs during alteration played some role in determining the present-day abundances, as, for example, Re and Au are fairly mobile under conditions of aqueous alteration (e.g., Colodner et al. 1992; Wallace et al. 1990b).
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Table 3.2.1.2.1. Abundance of PGEs and other siderophile elements in samples from K/T boundaries. Location
Co ppm
Ni ppm
Pd ppb
Re ppb
Os ppb
Ir ppb
Pt ppb
Au ppb
Caravaca
626
2580
110
2.7
46
56.9
131
43
Stevns Klint
146
1370
46
9.4
35
47.4
78
12.5
Data from Kyte et al. (1985).
The host phase of the PGEs is still not well known. Several proposals have been made over the years. For example, Doehne and Margolis (1990) reported on micrometer-sized Pt grains, whereas Martinez-Ruiz et al. (1997) described carbonrich cores in some K-feldspars from the Agost and Caravaca K/T boundary sections that contain Ir, Pt, Pd, and Ni. Robin et al. (1993) found that some spinelbearing spherules from DSDP Site 577 have Ir contents that range up to meteoritic values, but otherwise very few trace element analyses of spinel crystals are available (which is not surprising, given their small sizes). Recently, Kyte (1998) described a 2.5 mm diameter inclusion recovered from K/T boundary sediments at DSDP drill core 576 (western North Pacific), and interpreted this fragment to be a fossil meteorite. The implication is that this would be a fragment of the K/T boundary impactor. Unfortunately the piece seems to be completely altered, but may have preserved some primary textures. The main minerals present are hematite and clays, with some of the hematite containing submicrometer-sized Ni-Fe metal and Ni-Fe sulfide grains. In a bulk sample, this altered fragment has Ir, Fe, and Cr abundances that are within a factor of about 2 of chondritic values. However, the explanation of the chemical composition of the fragment may be quite complicated, as other elements show non-chondritic abundances or ratios. The abundances of lithophile elements (e.g., Sc or the rare earth elements) are higher by factors of about 50 to 100 compared to chondritic values. Worse even, Au has an abundance of 1000 times the chondritic concentration (213 ppm), which is very difficult to explain by any straightforward alteration process (Kyte 1998). The severe alteration complicates the interpretation of this fragment as a fragment of the K/T boundary bolide and does not allow to use the chemical data obtained from this piece to constrain the composition of the impactor.
3.2.1.3 Meteoritic Os- and Cr-isotopic signature Turekian (1982) proposed to measure the Os isotopic ratio in the K/T boundary clays, following the reasoning discussed in Sect. 1.8.3. Luck and Turekian (1983) subsequently analyzed marine manganese nodules and two K/T boundary clay
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samples. The manganese nodules had ~87Os/~88Osratios of about 0.7 to 1, showing a clear continental crustal signature, while the K/T boundary samples from Stevns Klint (Denmark) and Starkville South (Colorado, USA) yielded values of 0.200 and 0.155, respectively (Luck and Turekian 1983; see also Koeberl and Shirey 1997). These results indicate clearly that the PGE signature at the K/T boundary is not the result of the concentration of PGEs from a crustal source by terrestrial processes. Subsequent analyses by Lichte et al. (1986) showed a ~87Os/~88Osratio of 0.135 in clay for the Woodside Creek (New Zealand) K/T boundary. Kr~ihenbtihl et al. (1988), Esser and Turekian (1989), Schmitt (1990), and Meisel et al. (1995) determined comparable values, ranging from 0.137 to 0.212, for K/T boundary samples from Starkville South, Madrid, and Berwind Canyon (both Colorado, USA), Raton (New Mexico, USA), Shatsky Rise (DSDP 577), Stevns Klint, and Sumbar (Turkmenistan). Peucker-Ehrenbrink et al. (1995) found that the 187Os/~8Os ratio of seawater at the K/T boundary shows a sharp decrease, which they attributed to leaching of meteorite debris from the impact event. Meisel etal. (1995) measured the variation of the ~87Os/~8Os ratio across a K/T boundary section (at Sumbar, Turkmenistan) and found a significant and sudden decrease of the ~Os/~Os ratio from the end-Cretaceous rock layers to the actual K/T boundary clay that correlates with the maximum Ir (and Os) concentration; in the early Tertiary rocks, the l~Os/~8~Os ratio returns to higher values. Pearson et al. (1999) reported first Os isotope data on altered K/T boundary samples. All these studies provide clear evidence for an extraterrestrial component at the K/T boundary (and, together with other chemical and isotopic data, rule out a mantle source for the PGEs). Analyses of the PGE contents and the Os isotopic composition of a profile across the K/T boundary section at ODP 1049 (Blake Nose, western North Atlantic) are currently in progress (B. Peucker-Ehrenbrink and G. Ravizza, personal communication 1999). Unfortunately, despite the potential of the Os isotopic analyses, only very few K/T boundary sections, or any other boundary sections, have been studied in any detail. Recently, Shukolyukov and Lugmair (1998) reported on Cr-isotopic studies on K/T boundary samples (see Chap. 1.8.4 for details on this isotopic system). These authors presented evidence for a meteoritic component that is in better agreement with a carbonaceous chondritic composition of the impactor, rather than an ordinary chondritic composition.
3.2.1.4 Soot and Organic Chemistry Wolbach et al. (1985) found evidence for global wildfires in the form of a charcoal and soot layer at numerous K/T boundaries around the world, coinciding with the Ir-rich layer. The insoluble carbon fraction after acid dissolution is dominated by kerogen and elemental carbon. Kerogen is enriched about 15 times, and nitrogen is enriched 20 times, compared to the maximum abundances in the uppermost Cretaceous limestones (Gilmour et al. 1990). Both also show a marked change in
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their isotopic composition across the K/T boundary. No comparable soot enrichments of local or global distribution occur in the Late Cretaceous or in a wide range of other marine sediments (Wolbach et al. 1990). The presence of the hydrocarbon retene in the soot layer is diagnostic of wood fires in which resinous (coniferous) plants and trees were burning, indicating that most or all of the fuel was biomass (Wolbach et al. 1990). The isotopic composition of the carbon in the soot layer (average 513C-- -25.8%~) resembles that of natural charcoal and atmospheric carbon particles originating from biomass fires (Wolbach et al. 1990). From the isotopic composition of Chicxulub impact diamonds (see Sect. 3.2.1.7) we know that the isotopic composition of carbon in the target rocks is about -18 to -12%~; as the soot has a lighter isotopic composition, it should be derived from biomass burning rather than from the target rocks or the bolide (I. Gilmour, personal communication 2000). The total amount of soot in the atmosphere due to the global wildfires at the end of the Cretaceous has been estimated at 7.1016 g, which must have had a large influence on the environment. Fullerenes (large spherical molecules; the best known ones are made up of 60 or 70 carbon atoms) have also been detected in K/T boundary samples (Heymann et al. 1994, 1996). These authors found up to 5.4 ppb of C60 in K/T boundary clays from Woodside Creek and Flaxbourne River in New Zealand, which also have very high soot and elemental carbon contents (e.g., Wolbach et al. 1985; Gilmour 1998). Heymann et al. (1994, 1996) concluded that the fullerenes formed in global(?) wildfires that were ignited by radiation and hot melt from the K/T impact event (Melosh et al. 1990), rather than be the result of carbon chemistry in the hot vapor plume of the impact. Further evidence for global wildfires comes from the detection of fossil charcoal at K/T boundary locations (Kruge et al. 1994) and from the discovery of polycyclic aromatic hydrocarbons (PAHs) at several boundary locations in Denmark, Italy, New Zealand, and Japan (e.g., Venkatesan and Dahl 1989; Gilmour et al. 1990; Mita and Shimoyama 1999). Gilmour et al. (1990) also point out that the significant input of the toxic and carcinogenic PAHs into the biosphere as a consequence of the impact event must have had negative effects on the environment (as they did in freshwater ecosystems following the Mount St. Helens volcanic eruption in 1980). Arinobu et al. (1999) concluded, from their study of carbon isotope stratigraphy and the detection of a spike of pyrosynthetic PAHs at the Caravaca K/T boundary, that about 20% of the terrestrial (aboveground) biomass available at that time must have instantaneously combusted. Few measurements exist so far on sulfur isotopes across the K/T boundary (e.g., Schmitz et al. 1988; Kajiwara and Kaiho 1992), but a shift in the isotope ratio at the boundary is consistent with the effects of bacteria feeding on dead biomass. Another line of evidence in favor of an extraterrestrial event at the K/T boundary may the presence of large amounts of (supposedly) extraterrestrial amino acids that are associated with the boundary layer. They are absent in the boundary layer itself, but occur a few centimeters above and below (Zhao and Bada 1989). The two amino acids found - ~-aminobutyric acid (AIB) and isovaline - are both common in meteorites, but uncommon in the terrestrial biosphere. However, iso-
109
valine is common in soil fungi and AIB is an essential part of ATP-synthase and, therefore, present in all cells, casting some doubt on the suggestion that these amino acids are of extraterrestrial origin (I. Gilmour, personal communication 2000). On the other hand, Zhao and Bada (1989) reported that the isovaline is racemic (i.e., a mixture of both left- [L] and fight [R]-handed mirror forms of the molecule), whereas biogenic amino acids only occur in one form (L). It is interesting that such fragile molecules would survive the firestorm during the impact event. This led Zahnle and Grinspoon (1990) to propose that the amino acids were delivered from dust of a huge disintegrating comet, of which the K/T bolide was just the largest fragment. The dust would have slowly accreted onto the Earth. However, there is no evidence from 3He studies for an enhanced influx of extraterrestrial dust around the time of the K/T impact event (Farley et al. 1999), in contrast to a broad peak of influx in the Late Eocene (Farley et al. 1998). On the other hand, Becker et al. (1999) report a high 3He/4He ratio in samples of the K/T boundary clay from an unspecified location at the Raton Basin (USA), and from Stevns Klint (Denmark), and speculate that some higher fullerenes might be present and host the 3He. The study of fullerenes and 3He is obviously a controversial topic. However, Pierazzo and Chyba (1999) found, in a series of calculations, that a certain fraction of extraterrestrial amino acids from the bolide would not be destroyed during a somewhat oblique impact. This would provide a possible mechanism for amino acid survival during the K/T impact event, and obviate the need for a 3He-rich dust source.
3.2.1.5 Evidence of shock metamorphism The first clear evidence of shock metamorphism at the K/T boundary was found by Bohor et al. (1984) in the form of shocked quartz grains in sediments from the Brownie Butte location. This landmark discovery confirmed the hypothesis of Alvarez et al. (1980) that a large-scale impact event occurred at the end of the Cretaceous. Shocked quartz and feldspar, and other shocked minerals (Figs. 1.6.4.1 and 1.6.4.2) were later found at practically all K/T boundary sites around the world (see, e.g., Bohor and Izett 1986; Bohor et al. 1987a; Bohor 1990). The shocked quartz grains show multiple intersecting sets of PDFs with shock-characteristic crystallographic orientations. As discussed above, such shocked minerals are associated with pressures far beyond those of any endogenic processes and are uniquely characteristic of hypervelocity impact. No quartz or other minerals showing true shock metamorphic characteristics have ever been found in a volcanic environment (e.g., Sharpton and Schuraytz 1989; de Silva et al. 1990). Furthermore, the modal abundance of shocked minerals (quartzdominated), as well as the chemical composition of shocked feldspars at the K/T boundary, are indicative of a continental crustal source, and are not compatible with material derived from oceanic crust (Sharpton et al. 1990). Oceanic source rocks were initially proposed based on some mineralogical and geochemical data (e.g., Montanari et al. 1983; De Paolo et al. 1983). The discovery of clear evidence
110
for impact in terrestrial K/T boundary locations also helped to negate arguments that marine sites represented condensed sections.
Fig. 3.2.1.5.1. Shocked zircon from the K/T boundary at Berwind Canyon, Colorado. The crystal was etched and shows planar features. Scale bar on lower left is 20 gm wide (SEM photograph courtesy B.F. Bohor).
Shocked quartz grains show a variation in their maximum grain sizes with geographic location. The largest grain dimensions (>0.6 mm) are found at K/T boundary sites in the Western Interior of North America, and decrease with increasing distance from North America (cf. Bohor 1990). For example, at Stevns Klint (Denmark) they are on the order of 0.15 m m in size, and in New Zealand they reach 0.11 mm. This size distribution provided an early pointer to the possible source crater location. Later, Alvarez et al. (1995) provided a quantitative model of the geographical distribution of shocked quartz. Shocked zircons (Figs. 3.2.1.5.1 and 3.2.1.5.2), another signature of a continental crustal source, were discovered by Bohor et al. (1993). Shocked zircons display planar features (Fig. 3.2.1.5.1) with what appears to be multiple orientations, but it is unlikely that these features are PDFs s e n s u strictu, because PDFs are defined as planar features that contain amorphous material, which does not seem to be the case for shocked zircons (Leroux et al. 1999). Some shocked zircons, possibly those that experienced (incomplete?) melting, show a granular structure (Fig. 3.2.1.5.2). In addition to the finding of shocked minerals, the pres-
111
ence of the high-pressure quartz polymorph stishovite was also reported from K/T boundary sediments (McHone et al. 1989).
Fig. 3.2.1.5.2. Shocked zircon from the Berwind Canyon (Colorado) K/T boundary location. The sample was etched. The scale bar on the bottom of the left image is 40 gm wide. A close-up of part of the zircon crystal on the right side shows the internally granular texture, similar to what has been observed in Muong Nong-type tektites (see Fig. 2.4.3.4), and is thought to represent the result of higher shock pressures than those that form planar features (SEM photograph courtesy B.F. Bohor).
3.2.1.6 Impact glass Sigurdsson et al. (1991a, b), Izett (1991), and Kring and Boynton (1991) described the presence of rare relict glass within alteration spherules (that are otherwise very common at numerous K/T boundary locations; e.g., Smit and Klaver 1981; Smit and Kyte 1984; Pitakpaivan et al. 1994) from the K/T boundary at Beloc, Haiti, and interpreted the material as impact glass. Sigurdsson et al. (1992) have shown, from comparison with experimental glasses, that the Haitian glasses have been quenched from temperatures much higher than common for volcanic processes. A detailed study by Koeberl and Sigurdsson (1992) provided not only geochemical arguments for the impact origin of these glasses, but also demonstrated the existence of rare inhomogeneous glasses with lechatelierite and other mineral inclusions, which are typical for an origin by impact. Blum and Chamberlain (1992)
112
have obtained oxygen isotope data on Haitian glasses that specifically rule out a volcanic origin of these glasses. Blum et al. (1993) have confirmed this result with Rb-Sr and S m - N d isotopic data, showing that the Haitian glasses are mixtures of silicate rocks of upper crustal composition with a high CaO-endmember (e.g., limestone) (see also Premo and Izett 1992, and Bohor and Glass 1995). Chanssidon et al. (1994) have shown that the sulfur in the yellow glasses occurs in the form of sulfate, which is not compatible with a volcanic source. Koebefl (1992b) measured the water content in glasses from Haiti and found a range of 0.013 to 0.021 wt.% H20 (this was later confirmed by Oskarsson et al. 1996), which is further evidence for an origin by impact, as impact glasses are extremely dry. Koeberl et al. (1994c) have used Re-Os isotope systematics to find evidence for the presence of a small meteoritic component in the Haitian glasses. The Haiti glasses are different from tektites in some respects; for example, they are more oxidized than tektites (Oskarsson et al. 1996). Furthermore, high-precision age determinations on the Haitian glasses have shown that the materials have an age indistinguishable from that of the K/T boundary, at 65 Ma (e.g., Izett 1991; Swisher et al. 1992). Glasses with similar properties were later recovered from some K/T boundary locations in Mexico (e.g., Mimbral) as well (e.g., Smit et al. 1992a, b). It is interesting to note that, despite all the data favoring an impact origin of the Haiti glasses, a few authors have suggested that the glasses are of volcanic origin (e.g., Stinnesbeck et al. 1993), or that there is no evidence at all for impact ejecta at Beloc (e.g., Jehanno et al. 1992). However, some of the co-authors of the latter paper seem to have subsequently accepted that impact did play a role, as Rocchia et al. (1996b) proposed a model that involves "fragmentation of a single-incident bolide, colliding with the Earth at grazing incidence, with ricochet and rebound of fragments". However, such a process seems unnecessarily complicated and difficult to reconcile with cratering mechanics. In summary, all available evidence supports an impact, and not a volcanic, origin for the glasses from Beloc and other K/T boundary locations.
3.2.1.7 Impact-derived diamonds Small, nanometer-sized diamonds were first reported from K/T boundary sediments in Alberta, Canada, and were thought to be of extraterrestrial (meteoritic) origin (Carlisle and Braman 1991). More recently, larger diamonds have also been found at other K/T boundary locations (Gilmour et al. 1992), including some in Mexico (Hough at al. 1997). These diamonds, which have a unique C and N isotopic signature (cf. Gilmour 1998), are clearly connected to the impact process (and not of extraterrestrial origin as had been speculated by Carlisle and Braman 1991). Even though there is a similarity between the K/T diamonds and those found at known impact craters (e.g., Koeberl et al. 1997a; Langenhorst et al. 1999), it is, however, not yet clear if the K/T boundary diamonds also formed by shock processes (de Carli and Jamieson 1961), similar to those that are found in
113
proximal ejecta (e.g., E1 Goresy et at. 1999). Chicxulub diamonds are, so far, the only ones found in distal ejecta deposits.
3.2.1.8 Occurrence of spinel Magnetite contained in impact-derived spherules at the Petriccio section in Italy was first reported by Montanari et al. (1983), and later identified as magnesioferrite spinel by Smit and Kyte (1984). Spinels at the K/T boundary can be used as event markers, with abundance peaks similar to those observed for the PGEs. These spinels occur in a variety for morphologies (e.g., Fig. 3.2.1.8.1) and compositions, resulting from variable substitution of Mg for Fe 2+. The majority of the spinels describe a compositional range spanning the solid solution series between magnetite (Fe304) and magnesioferrite (MgFe204). Spinel crystals from Pacific sites display variable substitution of A13÷for Fe 3÷, ranging from magnesioferrite to pure spinel (MgA1204) composition (e.g., Kyte and Smit 1986). All K/T boundary spinels are highly oxidized (high Fe 3+content), and have high Ni (and Co) contents (a few measurements also indicate high Ir), but low Cr and Ti abundances. These compositional characteristics set them apart from most known igneous or metamorphic terrestrial spinels. Numerous studies have been performed on the spinels (e.g., Montanari et al. 1983; Montanari 1991; Smit and Kyte 1984; Kyte and Smit 1986; Bohor et al. 1986; Robin et al. 1992, 1993; Kyte and Bostwick 1995; Rocchia et al. 1996; Kyte et al. 1996, and references therein). Three main theories to explain their origin were discussed. They could form as: ablation debris from the impactor, crystallites in melt droplets, or vapor condensates in the hot fireball. The first theory, that the spinels form by a process analogous to the formation of ablation spherules that originate from small meteors in the Earth's atmosphere, was mainly proposed by Robin et al. (1992, 1993) and Gayraud et al. (1996), but it seems difficult to reconcile the global distribution of spinel with ablation from a large impactor that traverses through the atmosphere in a few seconds. This may be one reason why Robin et al. (1993) and Rocchia et al. (1996b) resorted to a very complicated process, in which fragmentation and secondary impacts are necessary; however, all the evidence collected so far favors one single large impact event. A more plausible origin for spinels is the formation in the hot vapor cloud of the impact. Kyte and Bohor (1995) provide a detailed assessment of this theory. They found that Ni-rich magnesiowtistite, a high-temperature mineral, is preserved in the cores of some larger spinel crystals, where it is intergrown with magnesioferrite. Kyte and Bohor (1995) suggested that this mineral, which does not form in terrestrial igneous systems, can only evolve in the hot fireball of the impact. In their model, magnesiowtistite-magnesioferrite intergrowths occur in droplets that equilibrate with the vapor at temperatures exceeding 2300 °C, where the refractory MgO is enriched in the liquid relative to the more volatile SiO 2. Kyte et al. (1996) cited further evidence in support of this model.
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Fig. 3.2.1.8.1. Skeletal magnesioferrite (etched) from the K/T boundary at DSDP Site 596 in the southwestern Pacific (54-55 cm layer). Scale bar on bottom left is 20 gm (SEM photograph courtesy B.F. Bohor).
3.2.2 Chicxulub Impact Structure: Relation to the K/T Event Despite substantial indirect and direct evidence for an impact event at the K/T boundary (as discussed in the previous sections), some individuals still refused to accept the idea of an impact and resorted to some equally non-uniformitarian and extremely rare endogenic processes to try explain the observations made. However, even though some of the more fanciful hypotheses could explain one oi" two features of the K/T boundary, they singularly failed to provide a complete explanation of all the evidence listed above. Therefore, all these points together provide rather straightforward evidence for an impact event at the end of the Cretaceous Period. Another point worth considering is that the deposition of the K/T boundary layer, with all its shocked minerals, spinels, spherules, etc., had to occur in a geologically very short timespan, probably on the order of a year or less (e.g., Preisinger et al. 1986). In the late 1980s, despite all the evidence that had been accumulated in support of a K/T boundary impact event, a major point of contention was the lack of a suitable large impact structure with an age of 65 million years. Crater diameters, as derived from estimates of total meteoritic material present at the K/T boundary
115
worldwide (e.g., Alvarez et al. 1980), were calculated to be on the order of at least 100 to as much as 200 km. Several craters were proposed, but a link with the K/T boundary event remained tenuous. Numerous proposals (some of them rather eccentric) were made before 1990 (see, e.g., Kring 1993, for a discussion). However, at that time at least two impact structures of medium to large size on Earth were thought to have an age identical to that of the K/T boundary. The first one, the Kara crater in Russia (estimated at about 65-80 km diameter) was thought to have an age of 65 M a (Nazarov et al. 1989); however, more precise age determinations showed that it is older than 65 M a (Koeberl et al. 1990; Trieloff and Jessberger 1992), with a most probable age of 70.3 Ma (Trieloff et al. 1998). Moreover, Nazarov et al. (1991) suggested that the Kara crater may be larger than 100 km in diameter, rather than the 65 to 80 km thought before, which would make it one of the largest impact structures known today. The other major contender for the title "K/T boundary crater" was the Manson structure in Iowa, which is discussed in Chap. 3.4; it turned out to be 74 million years old, and would have been too small anyway (37 km diameter) to explain the global effects.
Chicxulu~~
Gulf of Mexico
~)
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Peninsula ~ Caribbean Sea
r ........ ""-I" Mexico
\-
I
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Belize
/
r .... d ._£.. ,," Guatemala ,'~'-
~ 0 -
Honduras
Fig. 3.2.2.1. Geographical location of the Chicxulub impact structure on the NE part of the Yucatan (Mexico) peninsula.
As mentioned above, studies of K/T boundary distal ejecta around the world were used to constrain the location of the possible source crater. For example, from the analysis of the abundance and size variation of shocked quartz grains, it
116
was concluded that the source crater had to be somewhere on or near the North American continent (see, e.g., Kring 1993, for a discussion). However, it was not until 1991 that Hildebrand et al. (1991) proposed that a large buried structure in NE Yucatan (Mexico; Fig. 3.2.2.1) might be the elusive K/T boundary crater. This structure had been recognized earlier by Penfield and Camargo (1981), who suggested it to be an impact structure, but unfortunately their abstract was presented at a meeting of economic geologists, who apparently were not interested in impacts and extinctions (even though impact structures have been shown to contain economically important deposits, ranging from ores to hydrocarbons; for a review, see Grieve and Masaitis 1994). Following its confirmation as an impact structure, Chicxulub was studied extensively, mainly by geophysical methods. This was partly in response to a debate about the exact size of the structure (see below). In the following paragraphs, we will not discuss the whole literature that exists by now on Chicxulub, but just review the evidence that links Chicxulub to the K/T boundary event. This means that the geophysical data and the debate dealing with the diameter will only be mentioned briefly.
Fig. 3.2.2.2. Computer-generated image of the circular gravity anomalies at Chicxulub, showing the inner peak ring and several outer rings. The most conspicuous structure is about 180 km in diameter; the outer fourth ring is difficult to see (image COUl~esyV.L. Sharpton).
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Penfield and Camargo (1981) first recognized a circular gravity anomaly, which is similar to that of known impact structures (cf. Pilkington and Grieve 1992). The structure is marked by an extensive circular -30 mgal negative Bouguer gravity anomaly of about 180 to 200 km diameter, with a central 20 mgal high (Hildebrand et al. 1991). Sharpton et al. (1993) compiled a new gravity map, resulting in a by now famous computer-generated image (Fig. 3.2.2.2), from which they deduced the existence of three major rings and evidence of a fourth (somewhat irregular) outer ring structure with about 140 km radius. These data, and a general spacing rule for tings of multi-ring impact structures, prompted Sharpton et al. (1993) to interpret the feature as marking the outer limit of the basin rim crest, yielding a diameter of about 280 km for the Chicxulub structure. In contrast, Pilkington et al. (1994) maintain that their modeling does not show any evidence of a fourth outer ring and, thus, that Chicxulub has a diameter of only 180km. Some surface expressions that may be related to the Chicxulub structure (which does not have any true surface exposures), e.g., the distribution of sinkholes (Perry et al. 1995), seem to support a diameter larger than 180 km, probably on the order of 240 km (Pope et al. 1993, 1996). A part of the ring of cenotes (sinkholes) in Yucatan is shown in Fig. 3.2.2.3. A recent study of the horizontal gradient of the Bouguer anomaly over the structure by Hildebrand et al. (1995) was interpreted to be consistent with a 180 km crater diameter. On the other hand, another interpretation of the gravity data, in combination with drilling information, was made by Sharpton et al. (1996). Total magnetic field data indicate an anomaly about 180 to 210 km in diameter (e.g., Pilkington et al. 1994). The geophysical data were used by Schultz and D'Hondt (1996) to infer that Chicxulub formed by a bolide that impacted from a southeast direction at an angle of 20 ° to 30 ° from the horizontal. According to Schultz and D'Hondt (1996), this interpretation is also supported by the extinction patterns in North America. However, Pierazzo and Melosh (1999), in model calculation of Chicxulub as an oblique impact, were not able to reproduce the results of Schultz and D'Hondt (1996). Kyte and Bostwick (1995), on the other hand, interpreted the distribution of K/T spinels in the Pacific basin as indicating an oblique impact from the east. It seems that it is difficult to arrive at a conclusion regarding impact angle and direction. In view of the dispute over the diameter of Chicxulub, other data were necessary to decide between the opposing views. Early seismic data obtained during oil prospecting were only available in part (Camargo-Zanoguera and Sufirez-Reynoso 1995). Thus, a new detailed offshore seismic study, performed in the mid to late 1990s by an international consortium, yielded important new data (Morgan et al. 1997; Morgan and Warner 1999). These data show that Chicxulub is a multi-ring impact basin - the only one on Earth that is well preserved. It is generally assumed that Vredefort in South Africa (e.g., Reimold and Gibson t996) and Sudbury in Canada (e.g., Deutsch et al. 1995), which were both on the order of 250 km in original diameter before erosion and deformation, also represent multi-ring basins, but they are not well enough preserved for detailed studies. In such a case, the "diameter" of the structure is more or less a matter of definition (i.e., which is the
118
ring is assumed to give the "diameter"?). Morgan and Warner (1999) placed the crater rim at a diameter of about 145 km, which is surrounded by an outer ring at 180 km diameter and an exterior ring at about 250 km diameter. The latter one agrees with the data of Pope et al. (1996). At the center of the structure is a peak ring with a diameter of about 80 km. Whereas the size of the structure clearly has implications regarding the magnitude of the event and the amount of material ejected, petrographic and geochemical considerations are important to establish the link between the Chicxulub structure and the K/T boundary deposits. A major problem is that the structure is currently covered by severn hundred meters of post-impact Tertiary sediments, which requires obtaining drill cores. Samples from early drill cores obtained from Petr61eos Mexicanos in the 1950s and 1960s showed that two of the boreholes at the center of the structure penetrated a dense crystalline rock, which was initially thought to represent andesitic volcanic material, but is now recognized as impact melt rock (Hildebrand et al. 1991; Sharpton et al. 1992; Koeberl 1993b; Schuraytz et al. 1994). Samples fi'om the Y6 borehole, located about 60 km from the center of the structure, and from the centrally located C1 borehole were studied in most detail and showed the presence of a well-sorted, graded polymict breccia sequence and coherent melt rocks with glass remnants (e.g., Sharpton et al. 1992). The most important findings in the breccia and melt rock samples are clear, abundant evidence for the presence of shock metamorphism, including the following: a) abundant planar deformation features (PDFs) in quartz and feldspar crystals from crystalline basement clasts within the breccias and melt rocks (Sharpton et al. 1992); up to five sets of PDFs were found and measured by universal stage methods, showing the presence of the impact-characteristic orientations, with { 1013 }, or co, and { 1012 }, or g, orientations, being the most common; b) shock mosaicism in quartz and feldspar; c) diaplectic glass occurs as partly digested inclusions within glasses and melts; and d) impact melts, glassy and fine-grained recrystallization products. These findings provide unequivocal evidence for an impact origin of the Chicxulub structure. The presence of a meteoritic component in some of the melt rocks from the C1 and Y6 drill cores was indicated by elevated Ir contents of up to 13.5 ppb (Sharpton et al. 1992; Koeberl et al. 1994c; Schuraytz et al. 1994). However, the meteoritic component seems to be heterogeneously distributed; for example, Schuraytz et al. (1994) found pyrite crystals with high and variable contents of Ni and Co, and some opaque mineral grains that contained high Ir, which they interpreted as evidence for extensive post-impact hydrothermal activity. Koeberl et al. (1994c) used the Os isotopic system in a study of melt rocks from the C1 core and found elevated Os contents and low ~87Os/188Os ratios, indicating the presence of an extraterrestrial component. Schuraytz et al. (1996) found some micrometer-sized particles in Chicxulub impact melt rock samples that consist of almost pure Ir, which they interpreted as possible remnants of a carbonaceous chondrite-type impactor; this is at least in qualitative agreement with the Cr isotope data of Shukolyukov and Lugmair (1998).
119
Fig. 3.2.2.3. Radar image of the southwestern part of the ring of cenotes in Yucatan that seem to mark the outer limit (exterior ring) of the Chicxulub impact structure. The image is centered at 20 °N and 90 °W; southwest is up. (SIR-C/X-Space Shuttle image, NASA).
120
Isotopic measurements were of crucial importance to establish a link between the Chicxulub crater and the impact deposits found at the K/T boundary. Blum et al. (1993) measured the Rb-Sr, S m - N d , and oxygen isotopic composition of melt rocks from Chicxulub and found that, in a diagram of the oxygen versus the strontium isotopic composition (Fig. 3.2.2.4), the data for the Chicxulub melt rocks fall on a mixing hyperbola between the various types of impact glasses from the Haitian K/T boundary and a carbonate endmember (representing the carbonate platform rocks at Yucatan). The data indicate a common source for the Haitian impact glasses (i.e., K/T boundary impact ejecta) and the Chicxulub crater rocks. Manson Impact Melt (off scale)
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A similar result is obtained from plotting the Sr versus the Nd isotopic composition for Chicxulub melt rock samples and Haitian impact glasses (Fig. 3.2.2.5). The K/T boundary impact glasses and the Chicxulub melt rocks have similar values at about +58 and -3 for esr65 Ma and eNa65Ma, respectively. The depleted mantle Nd model ages of the Chicxulub rocks fall in a tight range of about 1040-1080 Ma, suggesting that the silicate endmembers of these breccias
121
and melt rocks had a source with a middle Proterozoic average crustal residence age, but younger sedimentation and crystallization ages (Blum et al. 1993). The data are also inconsistent with derivation from the mantle, because values for rocks derived from the upper mantle generally fall in a narrow range of end of +4 to +10%O and esr of -10 to -30%0.
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Shocked zircons that were found at distal K/T boundary sites (see Sect. 3.2.1.5) helped to establish another link between the K/T boundary and the Chicxulub structure. Krogh et al. (1993a, b) and Kamo and Krogh (1995) reported on singlezircon dating using the U - P b isotopic composition of zircons from various K/T boundary sites and from the Chicxulub crater. Fig. 3.2.2.6 shows a concordia diagram for shocked zircons extracted from an impact melt breccia from Chicxulub and from K/T boundary deposits in Colorado and Haiti. The data show a major intercept at about 545 Ma, indicating a Pan-African basement age. Zircons from a Canadian K - T boundary site gave more or less identical results (Kamo and Krogh 1995). The more highly shocked zircons give a partially reset U - P b age, with a lower intercept of 57 Ma. This is remarkably close to the impact age at 65 M a (in fact, if only zircons from one location are used, the data show less scatter and the intercept is closer to 65 Ma). Thus, the U - P b isotopic composition
122
o f zircons from the distal ejecta (from K/T boundary clay) agrees with that of zircons extracted from Chicxulub impact melt breccias.
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207pb/235u Fig. 3.2.2.6. Concordia diagram for U-Pb isotopic composition of shocked single zircons from K/T boundary sediments in Colorado and Haiti, and from Chicxulub impact breccia. The results for the three sites are indistinguishable. Most zircons define an upper intercept of about 545 Ma, with a lower intercept (defined by the most severely shocked zircons) of about 57 Ma, close to the impact age. A few zircons from the Chicxulub and Haiti locations have an upper intercept at about 4t8 Ma. The results demonstrate a common source for the K-T boundary ejecta and the Chicxulub impact melt breccias (diagram after Krogh et al. 1993, and Koeberl 1996).
The studies mentioned here have not only established Chicxulub as one o f the largest impact structures known on Earth, but have also shown that there are seve r n lines of evidence that link the distal K/T boundary ejecta with rocks from Chicxulub. Thus, an age determination for Chicxulub would confirm this link. Two detailed studies of the radiogenic age of the impact melt rock and impact glasses from the Chicxulub structure have been published early on. Sharpton et al. (1992) used hand-picked fragments of fine-grained impact melt rock (from the Y6 and C1 cores) for 4°Ar-39Ar step-heating age determinations. They found evidence for low-temperature alteration, but high-temperature increments in the age spectra of a sample from C1 give an age of 65,2 _+ 0,1 Ma, which they interpreted as the crystallization age. Swisher et al, (1992) were able to separate individual small glass fragments (0.4-0.5 m m in size) from the C1 impact melt rocks and were also
123
studied with the ~Ar-39Ar step-heating technique. As Swisher et al. (1992) seem to have succeeded in obtaining unaltered samples, they obtained better plateau ages than Sharpton et al. (1992). Two typical examples of the Chicxulub glass age spectra are shown in Fig. 3.2.2.7, with plateau ages of 64.94_+0.11 and 65.00 _+0.08 Ma. Swisher et al, (1992) found an average age of 64,98 -+ 0.05 Ma for their samples, which is indistinguishable from the age of 65.07 _+0.10 Ma that they obtained for impact glasses from the Beloc (Haiti) and Arroyo el Mimbral (Mexico) K/T boundary layers (cf. also Izett 1991).
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All the geochemical and geochronological data summarized in the previous paragraphs clearly confirm that Chicxulub is indeed the long-sought K/I" impact structure. It is of the right size, location, and age, and rocks from the structure show geochemical similarities with distal ejecta from K/T boundary layers.
3.2.3 Chicxulub and the K/T Mass Extinction We should at least briefly go back to the beginning of the whole story of the impact ejecta layer at the K/T boundary and the search for, and discovery of, the
124
Chicxulub impact structure, namely, that there was a major geological and biological event 65 Ma that prompted geologists and paleontologists to mark the end of the Cretaceous Period in the first place. This major event is marked by one of the largest mass extinctions of species during the last several hundred million years (e.g., Raup and Sepkoski 1982; Sepkoski 1990, 1992, 1996; Hallam and Wignall 1997). Geologists have, for a long time, been searching for a cause (or causes) to explain the end-Cretaceous and other mass extinctions. Large-scale volcanic eruptions, sea level fluctuations, and climate changes have been popular explanations. Extraterrestrial explanations (ranging from supernova explosions to cometary or asteroidal impact) were usually assumed to be unnecessary, with just a few exceptions (e.g., de Laubenfels 1956). Now that we know that there was at least one major impact event at the end of the Cretaceous, it would seem logical to assume that it played a major role in the mass extinction (e.g., McLaren and Goodfellow 1990). Interestingly enough, the paleontological community is still split over this question, with many workers maintaining that, in essence, "maybe there was an impact, but it had little or no influence on the biosphere". Clearly there was a mass extinction directly at the end of the Cretaceous, with more than half of all then living species becoming extinct. Some researchers maintain that there was no real mass extinction, but that some species became extinct in a gradual (even though accelerated) rate or in a stepwise extinction pattern, and that many species had become extinct well before the actual impact event, which is accepted as kind of a last straw that broke the camel's back (e.g., Keller et al. 1993; Stinnesbeck et al. 1993, 1997; Stinnesbeck and Keller 1996; Hallam and Wignall 1997; see also papers in Shavpton and Ward 1990, and in Ryder et al. 1996). On the other hand, the geochemical record indicates a sudden event (e.g., Alvarez et al. 1984), and there are workers who find no evidence for a stepwise extinction pattern in more or less the same K/T boundary sections, and who conclude that all extinctions were instantaneous (e.g., Pospichal 1994, 1996; Huber 1996; Smit 1982, 1999; Smit et al. 1988, 1996; see also other papers in Sharpton and Ward 1990, and Ryder et al. 1996). To resolve the question regarding stepwise or sudden extinctions, a blind test was conducted using the E1 Kef K/T boundary layer (Ginsburg 1997a; Smit et al. 1997). However, the results of the study (Canudo 1997; Masters 1997; Olsson 1997; Orue-etxebarria 1997; Keller 1997; Smit and Nederbragt 1997) led to no agreement between the different investigators, as they all seem to have obtained slightly different results (regarding the presence of certain Foraminifera in each sample), and, therefore, more or less maintained their original positions. Thus, the E1 Kef study was not considered a full success (Ginsburg 1997b). There are several reasons for this; as Kouwenhoven (1997) pointed out, the test was not really blind, as, for example, the participants received unprocessed samples and, being familiar with K/T boundary samples, they would have known fight away which samples are Maastrichtian and which are Danian. It seems that the resolution of the question regarding gradual versus sudden extinctions has to be addressed in a future "totally blind" test, such as a double blind test, similar to the ones that are commonly used in pharmaceutical studies.
125
The extinction of the dinosaurs at the end of the Cretaceous, which is probably the group of animals that caused the most publicity for K/T boundary studies, has been a similar point of contention. Many workers have maintained that they died out gradually over some time (which certainly must have happened), but also that there was an accelerated pace of extinction just before the impact event. However, the scarcity and large size of dinosaur bones in the geological record make it very difficult to obtain a high enough time resolution. Indeed, when very timeconsuming and labor-intensive studies at dinosaur fossil-rich locations are done, any perceived gaps in the fossil record disappear and no decline in the number of dinosaur species can be found (e.g., Sheehan et al. 1999). Early on, large-scale volcanism was cited as a probable main cause, not only for the end-Cretaceous extinctions in general, but also for the supposedly prolonged period of extinctions. The eruption of the flood basalts at the Deccan Traps in India was found to be coeval with the K/T boundary (e.g., Courtillot et al. 1996; Courtillot 1999). However, the flood basalts were emplaced over a period of less or equal to one million years (Courtillot et al. 1996), which is several orders of magnitude longer than the time of deposition for the K/T boundary layer. Also, studies of the Indian K/T boundary sections showed that the Deccan volcanism was neither triggered by the K/T impact (Boslough et al. 1996 discussed a possible mechanism for an impact to trigger flood basalt eruptions), nor does there seem to be any other causal relation (Bhandari et al. 1995, 1996). Also, Galer et al. (1989), in a Pb isotope study of K/T boundary samples, found that the Pb isotopic composition of the boundary layer does not isotopically resemble known Deccan Trap lavas. Thus, the Deccan volcanism may have contributed to the environmental conditions at the end of the Cretaceous, but it did not contribute to the sudden environmental changes that coincide with the K/T boundary. However, here is riot the place to provide an exhaustive discussion of the pros and cons of stepwise and sudden extinctions. Rather, we want to mention some of the environmental effects caused by the Chicxulub impact event. A major impact event at the specific geographic location of the Chicxulub crater, with abundant carbonate and anhydrite rocks of the Yucatan platform, must have had important consequences for the biosphere. During the impact event, thousands of cubic kilometers of rock and dust were ejected from the crater, and large amounts of water, CO2, and SO 2 must have been released into the atmosphere. Preliminary estimates (assuming about 300-2000 km 3 of vaporized sediments) yield sulfur masses of 3.5.1016 to 7 . 0 . 1 0 t7 g, and about 1019g of CO 2 that were released almost instantaneously into the atmosphere (Chen et al. 1994; Pope et al. 1994). Any detailed discussion or speculation regarding the long-term effects of such enormous amounts of gas in the atmosphere are beyond the scope of this volume (but see, e.g., Brett 1992; Chen et al. 1994; Pope et al. 1994; Lyons and Ahrens 1996; Baines et al. 1996).
126
Fig. 3.2.3.1. Quarry at Albion Island in northern Belize. The main layer of Chicxulub ejecta is visible as a distinct horizon in the middle of the quarry face. It is possible that the ejecta scoured the surface as they were moving away from the impact site in the form of a base surge (see Sect. 2.1) (photo courtesy J. Smit).
The exact amount of gases released varies b e t w e e n different m o d e l calculations (see, e.g., I v a n o v et al. 1996), and s o m e calculations indicate that the release of sulfur into the atmosphere had m o r e severe effects than the increase in C O 2 (Kring et al. 1996; Pierazzo et al. 1998). There is abundant e v i d e n c e for a short, but in-
127
tense, period of acid rain directly following the K/T impact (e.g., Crutzen 1987; Prinn and Fegley 1987), which influenced the extinction rate (D'Hondt et al. 1994, 1996). In addition, the marine sediments that comprised the Chicxulub target rocks also contained halogens (chlorine, bromine), which, when released into the upper atmosphere, destroy the ozone layer, leading to a substantial increase in the flux of mutagenic ultraviolet radiation at the Earth's surface. The atmospheric effects of large impacts have been reviewed by Zahnle (1990), Covey et al. (1994), and Toon et al. (1997); see also Emanuel et al. (1995) for the discussion of the possible influence of hypercanes (mega-hurricanes) in the end-Cretaceous environmental catastrophe. It is obvious that there must have been short-term, as well as long-term climatic changes that most likely led to the mass extinction that marks the K/T boundary.
Fig. 3.2.3.2. K/T boundary section at E1 Mimbral, Mexico, about 700 km from the outer limit of the Chicxulub structure, showing a complex succession of layers. The person on the left side (J. Smit) is standing on Cretaceous limestones; his height marks the thickness of the spherule-rich layer. This is overlain by a solid layer of a possible tsunami deposit. On the bottom of this deposit is occasional plant debris, whereas ripple structures in sandstone cap this unit, which is overlain by less consolidated Tertiary rocks.
No matter what the extent of the global effects of the impact were, the immediate destruction within several thousand kilometers distance from Chicxulub must have been catastrophic. For example, an unusual deposit of breccia-like material with a thickness of several tens of meters was found at a
128
quarry at Albion Island (not really an island; this is just the location name), in northern Belize, which was interpreted as the most proximal ejecta deposit of the Chicxulub crater found so far (e.g., Ocampo et al. 1996). Many K/T boundary sites in Mexico, Cuba, and even in the U.S. show thick and complexly layered deposits that have been interpreted as impact-induced tsunami deposits (e.g., Bourgeois et al. 1988; Iturralde-Vinent 1992; Hills et al. 1994; Smit et al. 1996). For example, the Pefialver Formation and its equivalents in northwestern Cuba, which contain Late Maastrichtian fossils, are characterized by a <180 m thick, normal-graded calcareous clastic deposit with a basal conglomerate, and have been suspected to represent a single event deposit, possibly as a result of a K/T impact-related tsunami. Takayama et al. (1999) reported on first evidence of shocked quartz in some of samples from these Cuban deposits. K/T boundary sections at most of the Mexican sites are characterized by a complex set of clastic sandstones, with coarse ejecta at the bottom and fine-grained ejecta, as well as a smeared-out Ir anomaly on top (Smit 1999).
Fig. 3.2.3.3. Plant debris at the base of the possible tsunami deposits at the E1 Mimbral K/T boundary location in Mexico.
One of the best known locations in Mexico is E1 Mimbral, which has been described in detail by Smit et al. (1992a, b, 1996). This section shows a succession
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from Cretaceous limestone into a spherule layer, which is overlain by a tsunami deposit and a zone with Ir enrichment on top, and capped by Tertiary units (Fig. 3.2.3.2). At the bottom of the tsunami deposit, plant debris, which was obviously ripped up and destroyed, has locally accumulated (Fig. 3.2.3.3). Deposits that are similar to the Mexican K/T sites were also found in Haiti (Maurrasse and Sen 1991), Guatemala (Stinnesbeck et al. 1997), and in Brazil (Albertao and Martins 1996) at the Poty K/T boundary section (cf. Albertao et al. 1994; Koutsoukos 1998). The top of the deposits that are interpreted to result from tsunamis is marked by current ripple structures that allow the measurement of paleocurrents (Smit et al. 1996). A particularly well developed exposure is shown in Fig. 3.2.3.4. In contrast, Bohor (1996) interpreted these deposits as an (impactinduced) Bouma sequence, whereas Stinnesbeck et al. (1993) and Stinnesbeck and Keller (1996) suggested that these horizons have been deposited over a longer time interval and represent sea-level changes. Smit (1999) summarized arguments why the latter two explanations are unlikely.
Fig. 3.2.3.4. Sedimentary structures in the K/T boundary deposit at La Lajilla, Mexico, showing abundant ripple marks that indicate about 200 individual current directions and are thought to have formed as a result of the interaction of large tsunami waves (e.g., Smit et al. 1996) (photo courtesy J. Smit).
Recently, K/T boundary sediments were studied at Blake Nose, off Florida in the Atlantic Ocean (Norris et al. 1999). Both seismic studies and analyses of cores from ODP Site 1049 indicate folding and slumping of sediments directly underneath the K/T boundary ejecta. Norris and Firth (1999) suggested that this was the
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result of a mass failure of the North Atlantic margin that was triggered by the K/T impact event, probably by seismic energy. The possibility of massive disruptions of the sea floor led Max et al. (1999) to speculate that this could result in the release of large amounts of methane gas from gas hydrates. The methane blowout may have added fuel for a global firestorm, which is documented in the soot layer at the K/T boundary. A similar methane release mechanism from ocean floor gas hydrates was recently proposed by Norris and Rrhl (1999) and Katz et al. (1999) to account for climate changes at the end of the Paleocene, at about 55.5 Ma. At this time the Earth's climate and oceans warmed up significantly within a short time (10 to 20 k.y.), with deep-ocean and high- latitude surface water temperatures rising by 4 to 8 °C (e.g., Kennett and Stott 1991). In addition, the carbon isotopic record shows a significant excursion towards lighter isotopic compositions, similar to what has been observed at the K/T boundary. Confirmation of a massive methane contribution to the global fires at the end of the Cretaceous will require a detailed study of the carbon isotopic evidence.
3.3 Late Eocene Impact Layers Late Eocene marine sediments around the world contain evidence for at least two closely spaced impactoclastic layers. Initially, it was thought that there is only one layer, namely the one known from the eastern U.S. coast, the Caribbean, and the Gulf of Mexico (e.g., Glass et al. 1973, 1979, 1984), which is correlated with the North American tektite strewn field (see above). This layer contains microtektites (i.e., glassy - not recrystallized - spherules), shocked minerals, and high-pressure phases (e.g., coesite) (e.g., Glass 1989), but no marked siderophile element anomaly. The presence of crystalline spherules composed mostly of clinopyroxene (cpx) was detected in the same deep sea sediments (e.g., Glass et al. 1985) and initially it was considered that these spherules also belong to the North American tektite strewn field (Glass and Bums 1987). The cpx sphemles were found not only in the Caribbean and the Gulf of Mexico, but also in the Pacific Ocean (e.g., Glass et al. 1985; D'Hondt et al. 1987). Glass and Burns (1988) proposed the name "microkrystites" for such impactproduced, crystallite-bearing spherules. More detailed work showed that the microtektite layer and the microkrystite (cpx) layer (both in middle to lower magnetic chron C15) are in fact separated from each other by about 25 cm, with the cpx layer being the lower (i.e., older) one (e.g., Keller et al. 1983, 1987; see also Obradovich et al. 1989). They also suggested that there is yet another, much older layer in middle to lower magnetic chron C16 at DSDP Sites 216 and 292 near Indochina. The separation between the two layers amounts to about 10 to 20 k.y. In contrast, Hazel (1989) argued for at least six different layers, i.e., that the impactoclastic layers at different sites represent different layers. This was disputed by Glass (1990), who concluded that there are only two layers. Miller et al. (1991) suggested that there are four layers and that the layer with microtektites and tektite
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fragments at DSDP Site 612 (e.g., Thein 1987; Koeberl and Glass 1988; Glass 1989) is much older than the North American tektite strewn field (and is correlated with the "old" layer at DSDP 216 and 292 of Keller et al. 1983, 1987). Such a proposal is not in agreement with the chemical and isotopic similarities between the DSDP 612 tektites and other North American tektites (e.g., Koeberl and Glass 1988; Glass 1989; Stecher et al. 1989). In a detailed assessment of the evidence, Wei (1995) came to the conclusion that there are only two layers (the older cpx layer and the about 10 to 20 k.y. younger North American microtektite layer), that those at DSDPs 216, 292, and 612 cannot be distinguished in age, and that all are in chron C16 rather than C15. The conclusion that there are only two distinct layers was recently supported by isotopic analyses reported by Whitehead et al. (2000) (see below). The assignment of absolute ages to the layers is difficult, as it depends on the time scale used (see Sect. 5.8 for more discussion). The microkr~stite layer has by now been found at numerous other locations, indicating that it has a more or less global distribution, and it seems to be associated at several locations with enhanced Ir abundances (see, e.g., Alvarez et al. 1982; Montanari et al. 1993). Impact ejecta that have been interpreted to be part of the cpx layer have also been found in rocks from the marine Umbria-Marche Sequence in Italy at the Global Stratotype Section and Point for the Eocene-Oligocene boundary at Massignano near Ancona (see Sect. 5.8.3). At this location the impactoclastic layer (dated at 35.5 + 0.3 Ma) is present as a 5 cm thick marly horizon containing altered microkrystites and Ni-rich spinel (Pierrard et al. 1998), shocked quartz with multiple sets of PDFs (Clymer et al. 1996; Langenhorst 1996), and enhanced Ir levels (e.g., Montanari et al. 1993; Pierrard et al. 1998; Huber et al. 1999) (see Sect. 5.8.4 for details). The recent findings by Glass and Koeberl (1999a,b) and Vonhof and Smit (1999), which were mentioned in Sect. 2.4.5.1, also indicated that the North American microtektite layer seems to extend to the southern Ocean near Antarctica and into the Indian Ocean and may, therefore, also have a near-global extent. Liu and Glass (2000) were able to confinn that both the microtektite layer and the microkrystite layer are present at Site 689B near Antarctica and deduced a separation of the two events by about 8 to 12 k.y. It is also interesting to note that Farley et al. (1998), in a study of the content of 3He in the marine sediments at Massignano, found a broad peak of 3He enrichment over a timespan of about 2 million years that coincides with the two Late Eocene impactoclastic layers. This isotope is a proxy for the influx of extraterrestrial dust, and is interpreted as indicating that during the Late Eocene there was a time of enhanced comet activity in the inner solar system, probably resulting in a higher impact rate than usual (see Chap. 5.8.4). So far, two large impact structures of Late Eocene age have been confirmed, namely the Chesapeake Bay structure off the eastern coast of the United States, and Popigai in Siberia, Russia (see below). Wanapitei (7.5 km diameter) and Mistastin (28 km diameter), both in Canada, are slightly older than Chesapeake Bay and Popigai (Table 1.9.1). Another structure of similar age may be the underwater structure at Fohn-1, North Bonaparte Basin, Timor Sea, which has been
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described by Gorter and Glikson (2000) as a possible impact structure of Late Eocene to pre-Miocene age. However, both the identification of this structure as an impact crater, and its age, have yet to be confirmed. The evidence presented by Gorter and Glikson (2000) is insufficient, as no indication of shock metamorphism exists and the geochemical data that allegedly indicate the presence of a meteoritic component are of low analytical precision and too close to the detection limit to allow such a conclusion. This leaves Popigai and Chesapeake Bay as the only two significant impact structures that coincide in age with the Late Eocene microtekrite and microkrystite layers.
3.3.1 Chesapeake Bay As discussed in Sect. 2.4.5.1, the 35 Ma Chesapeake Bay impact structure has now been identified with a certain degree of confidence as the source crater of the North American tektite strewn field (Koeberl et al. 1996c; Poag 1997b). The structure, which is not exposed at the surface, has a diameter of about 85 to 90 km, based on geophysical studies (Poag 1997b). An impact event that created a crater of this size would be capable of globally distributing its distal ejecta. The story of the discovery of this crater, the largest one known in the United States, is told by Poag (1999). The outline of the structure was determined on the basis of multichannel seismic-reflection profiles transecting the bay and nearly 60 bore holes drilled inside and outside the crater rim. The seismic profiles define the outer tim of the structure, which is 90 km in diameter (Poag 1997b). The gravity signature of the Chesapeake Bay structure (Koeberl et al. 1996c; Poag 1997b) is in agreement with observations from other complex impact structures. A fiat-floored, 300 to 1200 m deep, annular trough separates the outer rim from an irregular, lowrelief peak ring, with a 30 km wide inner basin in the center. Poag and Foster (2000) presented the first seismic evidence for 10 km diameter central peak. The pre-impact coastal plain rocks consist of a seaward-thickening wedge (3001200 m thick) of mainly lower Cretaceous to upper Eocene age, poorly lithified, sedimentary rocks, which is underlain by a crystalline basement complex comprising granitic and metasedimentary rocks of Proterozoic to Paleozoic age. Four drill cores have penetrated into the Exmore breccia: the Exmore, Windmill Point, Kiptopeke, and Newport News cores (Poag et al. 1992, 1994). The Windmill Point and Newport News cores were drilled just outside the crater rim, whereas the Exmore core was drilled near the outer rim of the crater, and the Kiptopeke core is located at the inner ring. No core is available from the center of the structure, however, or reaches basement (although a new drilling project is being planned to begin in 2000; C.W. Poag, personal communication, 1999). The Exmore samples contain a variety of lithologies. The section consists predominantly of poorly consolidated sedimentary units. In thin section, siltstones or sandstones (sometimes with glauconite) alternate with sedimentary and crystalline fragments derived from the basement. Most particulate samples consist of a mixture of sedimentary and crystalline rock types, as well as mineral fragments de-
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rived from granitoids. Intragranular deformation of felsic minerals (mainly quartz and feldspar) is often limited to non-diagnostic microdeformafion features, such as poorly developed irregular fracturing, undulatory extinction, and occasional kinkbanding of mica, and locally strained calcite (Koeberl et al. 1996c). In a study intended to confirm the impact origin of the Chesapeake Bay structure, Koeberl et al. (1996c) reported the finding of evidence for shock metamorphism in 14 Exmore core breccia samples from 372.0 to 415.6 m depth. Some samples exhibit characteristic microfracture patterns, which indicate shock pressures of 5 to 10 GPa, and shock mosaicism in quartz. These authors also found abundant occurrences of shocked quartz grains with PDFs in individual quartz grains and crystals from granitic fragments. The PDFs in quartz from the in the Chesapeake Bay core samples showed up to 6 different sets per grain (Koebefl et al. 1996c). Shock deformation was also found in K-feldspar, alkali feldspar, and plagioclase, which show up to three sets of PDFs. Several shocked K-feldspar grains also display local, incipient melting. A number of particulates also contain individual granitoid-derived rock fragments, which are partially or almost totally melted. These fragments represent impact melt, because they commonly incorporate shocked quartz and feldspar clasts. The measurement of the crystallographic orientation of the PDFs in quartz showed the dominance of the shockcharacteristic orientations and confirmed the impact origin of the Chesapeake Bay structure. The chemical composition of breccia samples from the Exmore breccia (recalculated on a water-free basis) is in good agreement with the composition of North American tektites and was taken by Koeberl et al. (1996c) to suggest that the tektites were derived from the Chesapeake Bay structure. However, more detailed chemical and isotopic studies, including the determination of the Sr and Nd isotopic compositions of the target rocks at Chesapeake Bay, are still in progress. The results from these studies should be sufficient to confirm (or reject) the link between Chesapeake Bay and the North American tektites.
3.3.2 Popigai There is a second large crater with an age that is indistinguishable from that of the Chesapeake Bay structure and the two ejecta layers, namely the 100 km diameter Popigai impact structure in Siberia, which has been dated by Bottomley et al. (1997) at 35.7 _+0.8 Ma. The Popigai structure is exposed in Archean crystalline rocks of the Anabar Shield, with overlying Proterozoic to Mesozoic sedimentary sequences (e.g., Masaitis 1994; Vishnevsky and Montanari 1999), and is the largest Cenozoic crater on Earth. Archean basement rocks, which are exposed to the south of the structure, comprise the Verkhne-Anabar and the Khapchan series. These rocks are strongly deformed and belong mainly to amphibolite and granulite facies of regional metamorphism, with various gneisses being the dominant rock type. The average composition of impact melt rocks from Popigai is similar to that of the average composition of Anabar Shield gneisses (Vishnevsky and Montanari
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1999). Minor occurrences of ultrabasic rocks (amphibolized and serpentinized peridotites and pyroxenites) occur within the gneisses, as do granitoids of various compositions that make up about 10% of the gneiss volume. The sedimentary cover has a total thickness of about 1.6 km and ranges from quartz arenites, dolomites, and sandstones of Proterozoic age to Cambrian dolomites, marls, and limestones, to Permian sandstones. A Mesozoic cover is exposed in a few locations to the northeast of the structure and includes Triassic volcanosedimentary formation (which are not found in any impact breccias), some Jurassic marine and continental formations, and Cretaceous siltstones, sandstones, coal-bearing sands, and clays, all of which feature prominently in suevitic breccias at the crater (e.g., Vishnevsky and Montanari 1999).
Fig. 3.3.2.1. Radar satellite image of the Popigai impact structure, showing the extent of the circular basin that makes up the structure with a diameter of about 100kin. (Source: gdcinfo.agg.cmr.ca/crater/world craters.html)
Details about the geology of the Popigai structure are given in the reviews of Masaitis et al. (1980), Masaitis (1999), and Vishnevsky and Montanari (1999). The structure is a circular basin (Fig. 3.3.2.1) that is characterized by several ring features, but lacks a topographic outer rim. It is separated from the surrounding areas by a complex concentric zone of uplifted and overturned blocks and klippen of about 100 km in diameter. Slightly deformed rocks extend to a maximum distance of about 70 km from the crater center. The structure hosts a large variety of impactites, including suevites, impact melt rocks, and other impact breccias. These are described in detail by, e.g., Masaitis (1994) and Vishnevsky and Montanari (1999).
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Fig. 3.3.2.2. Megabreccia at the Popigai impact structure, exposed on a cliff at a river. The polymict breccia contains clasts that range in size up to several tens of meters (photo courtesy P. Claeys).
Fig. 3.3.2.3. Thick layer of impact melt rock at the Popigai impact structure in Siberia. The melt rock overlies more fragile megabreccia deposits that is more susceptible to weathering (photo courtesy P. Claeys).
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Popigai is characterized by thick breccia and impact melt deposits of impressive appearance. Fig. 3.3.2.2 shows a megabreccia deposit that is exposed at a fiver and comprises a polymict breccia with clasts that are up to several tens of meters in size. Fig. 3.3.2.3 shows a cliff made up of an almost 100 m thick layer of impact melt rock (locally named "tagamite"), having an appearance that is similar to that of a volcanic lava flow. These melt rocks, however, were found to contain evidence for an extraterrestrial component, and undigested or partly digested clasts within the melt rock contain shocked minerals. Impact-derived diamonds have been found in impact melt rocks within the crater (e.g., Koeberl et al. 1997a) and at distances of up to 500 km from the structure (e.g., Vishnevsky and Montanari 1999), but it is not clear if they have weathered out of ejecta or have been transported by glacial action. It is now commonly assumed (e.g., Vonhof et al. 1995) that the global Late Eocene microkrystite layer originated from the Popigai impact event. Confirmation of such a link has to be done by using isotope geochemical methods, as radiometric age determinations do not allow to resolve an age difference of 10 or 20 k.y. First results of such a study were recently reported by Whitehead et al. (2000). These authors analyzed the Rb-Sr and Sm-Nd isotopic compositions of composite samples (1 to 9 rag) of microtektites and microkrystites from DSDP Sites 216, 462, and 612. Site 216 (eastern Indian Ocean) represents the slightly older layer, and Site 612 (eastern coast of the U.S.) represents the slightly younger layer that has been associated with the North American tektite strewn field and the Chesapeake Bay impact structure. Site 462 is located in the western central Pacific. The results of Whitehead et al. (2000) show that samples from Sites 216 and 462 have isotopic compositions that are similar to those of impact melt rocks from the Popigai impact structure, and are distinct from the Site 612 samples, which (in a eN~ vs es~ diagram) plot within the field defined by North American tektites. Both are isotopically distinct from Mistastin and Wanapitei impact melt rocks. The Nd model ages of Site 216 and 462 samples als0 fit the Popigai impact melt rock model ages and distinct from those of the North American tektites. These results seem to confirm the association of the lower of the two Late Eocene impactoclastic layers with the Popigai impact structure and also that two large impact events occurred at that time within a few tens of thousands of years.
3.4 Manson Impact Structure and Ejecta Layer The Manson impact structure is a nearly circular feature with a diameter of about 35 to 37.8 km, centered at 42 ° 35' 05" N and 94 ° 33' 33" W, slightly north of the town of Manson in north-central Iowa (Koeberl and Anderson 1996a). Although there is no surface expression of the structure, it was identified as a well-preserved complex impact structure that has a large central peak with a central depression. Although impact rocks are found at the bedrock surface, the region is covered by 30-100 m of Pleistocene glacial drift. The pre-impact surface of the region was
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covered by about 0.1 km of Cretaceous marine shale-dominated sediments, overlying about 0 . 8 k m of carbonate-dominated Paleozoic strata, and a southeastward-thickening wedge of poorly-consolidated Middle Proterozoic sandstones, siltstones, and shales ranging in thickness for zero to about 3 km within the structure, all resting on an Early to Middle Proterozoic gneiss- and granite-dominated basement (see, e.g., Hartung et al. 1990; Anderson et al. 1996; as well as papers in Koeberl and Anderson 1996). The area of the crater has been known as an area of anomalous geology since the beginning of the 20th century because of samples recovered during the drilling of a Manson town well and the unusually "soft" water produced by the well. Over the decades, several explanations were proposed for the origin of the Manson "anomaly", ranging from a cryptovolcanic feature, to a cryptoexplosive feature, and, finally, an impact structure (see Hartung and Anderson 1988, for a review). Early dating attempts of rocks from the Manson structure by A r - A r dating by Kunk et al. (1989) indicated that the structure may have formed at 65.7 Ma, an age indistinguishable from that of the K/T boundary. The possibility that a sizeable impact structure in the U.S. could be associated with the end-Cretaceous mass extinction led to an increase in research on the Manson structure (see Hartung and Anderson 1988, and Hartung et al. 1990, for reviews). The Iowa Geological Survey Bureau and the U.S. Geological Survey began in 1991-1992 a joint research core drilling program at Manson; one of the driving forces was the possibility that there is a link between the structure and the K/T boundary. Over 1200 m of core was recovered from 12 locations that are representative for the different parts of the structure. One of the first products of the investigation of the core materials recovered was a new and more accurate age for the formation of the Manson structure. 4°Arfl9Ar analysis of sanidine feldspar (recrystallized from impact melt) by Izett et al. (1993) showed that the age of the Manson structure was 73.8 _+0.3 million years, which is 9 million years prior to the age of the K/T boundary. More recently, Izett et al. (1998) determined a more precise age of 74.1 _+0.1 Ma. Papers by a number of authors, describing results dealing with 1200 m of core and numerous sets of samples from water well cuttings from the Manson impact structure, as well as geophysical studies of the crater structure, are collected in Koeberl and Anderson (1996a), and provide a fairly complete and detailed summary of our knowledge of the second-largest impact structure known in the United States. Izett et al. (1993, 1998) and Witzke et al. (1996) also described the discovery of a distal ejecta layer related to the Manson impact structure in the Crow Creek Member of the Cretaceous Pierre Shale in South Dakota and Nebraska (Fig. 3.4.1). This unit, which consists of a silty and sandy laminated limestone and an overlying marlstone, and has a thickness of about 3 m. Izett et al. (1998) conclude that the stratigraphic age of this unit is identical of the (radiometric) age of the Manson structure, and supported this conclusion by A r - A r age determinations on bentonites from the Pierre Shale in central South Dakota. Izett et al. (1993, 1998) and Witzke et al. (1996) report the finding of shocked minerals (mainly quartz and feldspar, possibly a few zircons) from rocks of the Crow Creek Forma-
138
tion. Izett et al. (1998) noted that the shocked quartz grains with multiple sets of PDFs are most common in the lower part of the Crow Creek Member, but some are also found in the overlying marlstone. These authors also found that the largest shocked quartz grains, with diameters of 1.5 to 3.2 mm, are found closer to the Manson structure (215 to 315 km), than those with smaller sizes (0.1 to 1.2 mm), which are found 410 to 475 km from Manson. This represents a range of 12 to 26 crater radii from the source crater. The mode of origin of the Crow Creek Member is not yet clear. Witzke et al. (1996) favored normal marine transgression, whereas Izett et al. (1993, 1998) prefer an interpretation in which the Crow Creek Member was deposited during an impact-triggered tsunami. No matter which interpretation is correct, Manson is one in a short list of impact structures that has been linked to a distal ejecta layer.
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Fig. 3.4.1. Location of the ca. 37 km diameter Manson impact structure in Iowa, with the generalized paleogeographic outlines of the Cretaceous edge and Pierre Shale edge at about 74 Ma. Numbered open circles mark locations where distal ejecta of the Manson impact event have been found within the Crow Creek Member of the Pierre Shale (for details, see Witzke et al. 1996).
3.5 Acraman Impact Structure and Ejecta Layer Gostin et al. (1986) reported on the discovery of an impactoclastic layer within Late Precambrian shales of the 590 Ma Bunyeroo Formation in the Adelaide geosyncline, South Australia. This layer contains abundant shocked quartz grains wit PDFs, shattered mineral grains, and small shatter cones (e.g., Wallace et al. 1990a). The ejecta were found in outcrops and drill cores over several hundred kilometers. At the same time, Williams (1986, 1994) identified the Acraman
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structure in South Australia as an impact structure, and confirmed it to be the source crater of the Bunyeroo impact ejecta layer. Gostin et al. (1989) and Wallace et al. (1990b) detected enrichments of the PGEs in the ejecta layer; however, post-formational redistribution had altered the PGE patterns. The diameter of the Acraman structure is at least 90 km, with some outer arcuate features at 150 km diameter (Williams 1994). Impact ejecta have been found at distances of up to 450 km from the Acraman structure (i.e., about 10 crater radii), making this a true distal ejecta layer. The impact ejecta at the Bunyeroo Gorge have been subdivided by Wallace et al. (1996) into several sublayers. These are: a) the lowest one is discontinuous (occurs as lenses) and comprises a sandy clast-bearing horizon containing mostly centimeter-sized fragments (rarely up to 40 cm in diameter); it is coarse material that may have been transported entrained in an ejecta curtain and was deposited in the water column shortly after the impact; b) An overlying porous graded sandstone layer, which may finer material that settled from the air; c) on top is a greenish-gray mudstone host rock layer with dark red impact ejecta clasts that had sunk into the mudstone. The first two layers contain abundant evidence of shock metamorphism, including quartz grains with multiple sets of PDFs and recrystallized impact glass fragments. Gostin and Zbik (1999) also reported the presence of rare shocked zircons with distinct and closely spaced planar features from ejecta clasts. Compston et al. (1987) tried to use zircons from Acraman ejecta to date the age of the impact, but their zircons were much less shocked than the ones described by Gostin and Zbik (1999) and gave, therefore, only the age of the target rocks. The ejecta show abundant evidence of low temperature alteration, which helps to explain the redistribution of the meteoritic component in the ejecta (e.g., Wallace et al. 1990b).
3.6 Morokweng and the Jurassic-Cretaceous Boundary A large, near-circular aeromagnetic anomaly in the region around the town of Morokweng, approximately centered at 23 ° 32' E and 26 ° 20' S, close to the border with Botswana in the Northwest Province of South Africa, had long been interpreted as the expression of an intrusive body. However, reinterpretation of regional gravity and aeromagnetic images, as well as the first reports of impact characteristic shock metamorphic effects in rocks from the Morokweng area, demonstrated the presence of a large meteorite impact structure (see, e.g., Corner et al. 1997). The size of the Morokweng impact structure is still the subject of debate, but it must have been larger than 70 km, which is the diameter of the present composite magnetic anomaly. Early estimates (e.g., Corner et al. 1997) proposed original diameter values in excess of 300 km, but more recent work on a deep drillcore near the structure (Reimold et al. 2000) failed to turn up evidence that this core penetrated through impact deposits. This may limit the diameter to
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about 80 kin. On the other hand, circular paleogeographical features surrounding Morokweng have a diameter of about 200 km (Reimold et al. 1999). Koeberl et aL (1997c) presented petrographic, chemical, and isotopic data for an impact melt body (which is also the cause of the magnetic anomaly) in the Morokweng structure. Disregarding a small number of obviously altered melt rock samples, the Morokweng melt body is extremely homogeneous in composition. Variations for major elements do not exceed 2-5 relative percent. Chemical analyses revealed that the impact melt rock contains significant abundances of siderophile elements with average values for Cr of 440 ppm, of 50 ppm for Co, 780 ppm for Ni, and up to 30 ppb for Ir. No variations with depth and no differences between drill cores were noted. In light of petrographic and isotopic evidence for the melt rock cited by Koeberl et al. (1997c) and Reimold et al. (1999), it can be excluded that mantle-derived sources are responsible for these high siderophile element concentrations. Abundances of the other platinum group elements confirmed a near-chondritic composition of this component. After correction for indigenous components, Koeberl et al. (1997c) concluded that a meteoritic (chondritic) component of 2-5% was present in the Morokweng melt rock. Chromium isotopic data of Shukolyukov et al. (1999) confirmed the presence of a meteoritic component and indicated a probable L-chondritic source. Koeberl et al. (1997c) also reported single zircon U-Pb and Th-Pb ages for the Morokweng impact melt rock of 144.7 _+0.7, and 146.2 _+ 1.5 Ma, respectively. This age is, within error, indistinguishable from the currently accepted age for the Jurassic-Cretaceous boundary, which is placed at 145 Ma at the base of the Berriasian (Harland et al. 1990; Gradstein et al. 1994). In comparing these ages, however, one has to bear in mind that the age of the Morokweng structure is a radiometric age, whereas the Jurassic-Cretaceous (J/K) boundary age value is based on interpolated stratigraphic ages. This apparent coincidence suggests a causal relationship. However, the Morokweng situation is somewhat different from that of the Cretaceous-Tertiary (K/T) boundary, where a well-defined and firmly dated impact-derived layer marks the boundary. There is no equally welldefined stratotype for the J/K boundary and there are only a few well-documented boundary locations in the world. Whereas there is a report of some PGE enrichments in a J/K boundary site in Siberia, with associated microspherules (Zhakarov et al. 1993), these data have yet to be confirmed. It is also not sure that the Siberian layer is really marking the J/K boundary (Rampino and Haggerty 1996). The exact stratigraphic placement of the J/K boundary is still a matter of debate, as the cross-calibration of the biostratigraphic time scale with the paleomagnetic time scale was marred by uncertainties in the numerical calibration of each time scale (Remane 1991). However, paleomagnetic analyses within the last 15 years (e.g., Ogg and Lowrie 1986; Bralower et al. 1989) have provided a more solid basis for global correlation of the J/K boundary event. Several authors have recently placed the boundary between the Tithonian (Uppermost Jurassic) and the Berriasian (Lowermost Cretaceous) stages at approximately 145 Ma (Harland et al. 1990:145.5 _ 2.5 Ma; Gradstein et al. 1994:144.2 _ 2.9 Ma).
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Whereas earlier workers did not assign much importance to the J/K boundary (cf. Remane 1991), Raup and Sepkoski (1984), Sepkoski (1992), and Sepkoski (cited in Rampino and Haggerty 1996) now consider the J/K extinction as one of the large extinction events of that last few hundred million years. Rampino and Haggerty (1996) interpreted data from these papers to indicate that the J/K extinction is the fifth-largest extinction event during the last 300 million years, as mainly recorded by marine genera and reptiles. Some evidence has been cited to suggest that the extinction events occurred at slightly different times in the Boreal and Tethyan provinces (cf. Ogg and Lowrie 1986; and M. Rampino, personal communication, 1997). For example, the boreal J/K boundary (offshore Norway) has been placed between the Volgian and the Ryazanian stages at an interpolated age of 142 _+2.6 Ma. It is interesting to note that the top of the Volgian offshore Norway is marked by impact ejecta from the nearby 40 km diameter Mj¢lnir impact structure (Dypvik et al. 1996). More recent data (H. Dypvik, personal communication, 2000) places the late Volgian at about 150 Ma. None of the data can be directly compared, as different timescales are used. It is also difficult to use biostratigraphical correlations to determine if the J/K boundary represents a global event, because of limited faunal exchange between different paleobiogeographic provinces. Gosses Bluff (Australia) has also a similar age (Table 1.9.1). The formation of a large impact crater of about 80 km diameter (possibly even larger) may have had some environmental and biological consequences. It may be speculated if the lesser extinction rate at the J/K boundary compared to the K/T boundary could be the result of a difference in target rocks. Whereas the bolide that formed the Chicxulub crater in Mexico hit a sequence of crustal rocks overlain by carbonate and evaporite rocks, leading to the release of enormous quantities of CO 2 and SO2 (with associated environmental consequences; Sect. 3.2.3), the Morokweng impact event occurred mainly in granitoids. No clear evidence has yet been found for distal impact ejecta at the J/K boundary. Kudielka et al. (1999) presented some preliminary stable isotope data across the Bosso River section in the Umbria-Marche sequence, which seems to be one of the best preserved J/K exposures (see Sect. 5.4). However, in the section analyzed so far, neither the carbon nor the oxygen isotope ratios show any significant shifts, which implies that there was no apparent disruption of the carbon cycle at this locality. Thus, the search for possible distal ejecta deposits associated with the Morokweng impact structure has to go on. If none are found, several interpretations are possible. First, Morokweng might have been too small to cause distal ejecta, or the small amount initially deposited might be eroded. Second, and more likely, the bad stratigraphic control on the exact position of the J/K boundary could mean that it is very difficult to locate the boundary (and the probably very thin ejecta layer), or maybe the impact event was not quite coeval with the end of the Jurassic. In any case, the tantalizing prospect remains that the end of the Jurassic is marked by one or more large impact events.
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3.7 Other Confirmed and Possible Ejecta Layers There is a number of layers in the sedimentary record that have been interpreted, by some workers, as being the result of impact processes (e.g., Archean spherule layers in South Africa and Australia). In addition, evidence of impact events has either been confirmed (Late Devonian) or suggested (Permo-Triassic and Triassic-Jurassic boundaries). In none of these cases has it been possible (so far) to detect a source crater. The cases discussed in the next sections do not provide an exhaustive discussion of every impactoclastic layer ever proposed, but are intended to describe some of the more important layers or boundaries.
3.7.1 South African and Australian Archean Spherule Layers Spherule layers in the approximately 3.4 Ga Barberton Greenstone Belt, South Africa, have been interpreted by Lowe and co-workers (e.g., Lowe and Byerly 1986; Lowe et al. 1989; Kyte et al. 1992; Byerly and Lowe 1994) as the result of large asteroid or comet impacts onto the early Earth. The enrichment of siderophile elements, especially the platinum group elements (PGEs), in these layers was taken by these authors as key evidence for the presence of an extraterrestrial component (Lowe et al. 1989), although some fractionations were noted (Kyte et al. 1992). The interpretation of these spherule layers as the result of impact processes has been challenged by Buick (1987), French (1987), Koeberl et al. (1993), and Koeberl and Reimold (1995). Fig. 3.7.1.1 shows a sample of the Barberton spherule layer. Koeberl and Reimold (1995) reported on detailed petrographical and geochemical studies, from which they made a number of observations that are either not supporting the impact hypothesis, or even contradicting it. The textures of most spherules are not necessarily the result of impact, but could instead be the product of radial or intersertal growth of crystals during secondary mineral formation (Fig. 3.7.1.2). There is no difference in the content of siderophile elements between spherule layers and layers devoid of spherules. The siderophile element abundances are high where sulfide minerals (e.g., pyrite, gersdorffite, and chalcopyrite) and/or chromite are present, independent of the presence or absence of spherules. High contents of, e.g., Ir (up to 2700 ppb), Ni (0.96 wt.%), and Cr (1.6 wt.%) were found in various samples. Abundances of these elements in chondritic meteorites are approximately 600 ppb, 1.4 wt.%, and 0.35 wt.%, respectively, resulting in respective meteoritic components in these samples of 450%, 70%, and 460% by weight. Such superchondritic concentrations cannot be primary meteoritic signatures (iron meteorites do not have high Cr or chondritic interelement ratios). Impact melt rocks have typically <<1% of a meteoritic component. Furthermore, spherules of any kind are very rare in known impact deposits (see, e.g., Graup
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1981, for a discussion of spherules at the Ries impact structure). Even at the K/T boundary, spherules are rare and occur only in layers at distal sites with a thickness of less than a few centimeters. If present at all, they are not usually associated with any significant Ir or PGE anomaly.
Fig. 3.7.1.1. Polished slab of a sample (BA-1; from the Princeton section of the Agnes Mine) of one of the early Archean spherule layers in the Barberton Mountain, South Africa, area. The sample is described in detail by Koeberl and Reimold (1995) and shows several sublayers, in which spherules (some of them deformed) exhibit evidence of size sorting.
It is likely that the high abundances of the siderophile elements in some Barberton samples and their enrichment in secondary minerals resulted from remobilization and reconcentration of these elements. Due to different distribution coefficients of the PGEs in hydro- and mesothermal processes, the interelement ratios should have changed during remobilization as well. Thus, the PGE abundance patterns and ratios are not primary and cannot be used as an argument in favor of an impact origin either. Nickel-rich Cr-spinels have chemical compositions that are totally unlike those of (undisputed) impact-derived spinels, e.g., those from the K/T boundary or from Late Eocene impactoclastic layers. There is no indication of any evidence of shock metamorphism, the commonly accepted definitive criterion for recognition of impact, in any samples from the Barberton spherule layers, which is unusual, because such evidence is preserved even in heavily altered samples from deeply eroded Archean impact structures, such as the 2.02 Ga Vredefort structure in South Africa (e.g., Reimold and Gibson 1996).
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Fig. 3.7.1.2. Thin section photograph of early Archean spherules from the BA-1 sample (see Fig. 3.7.1.1), showing the deformation of the sphernles and the internal textures. The mineralogical composition of the spherules is not significantly different from that of the matrix and indicates severe alteration and recrystallization. Width of image 2.2 ram, crossed polarizers (photo courtesy W.U. Reimold).
These observations provide serious problems for the interpretation of the Barberton spherule layers as "impact spherules". On the other hand, recent Cr isotopic analyses of several spherule layer samples from the Barberton area (Kyte et al. 1999; Shukolyukov et al. 2000) are in agreement with part of the chromium in the samples being of extraterrestrial origin and suggested that (a) carbonaceous chondritic projectile(s) could have been involved in the formation of these layers. These data seem to provide good evidence for an impact origin, but the issue is probably more complicated. It also became clear that the initial petrographic and geochemical arguments of Lowe et al. (1989) were ambiguous and in conflict with what is known from practically any other confirmed impact structure or ejecta deposit on Earth (Koeberl and Reimold 1995). No mechanism for the formation of such thick layers of spherules is known. It is equally peculiar that a meteoritic component would be present at levels that are four orders of magnitude above those normally observed in impactites and up to a factor of 5 above bulk meteorite compositions. Clearly this implies secondary alteration and redistribution, in which case there is no explanation why the PGE interelement rations would remain constant during the redistribution. If the observation by Shukolyukov et al. (2000) of extraterrestrial Cr in the spherule layers is confirmed and the link with the formation of the spherules themselves is substantiated, this would indicate that some very unusual and poorly understood processes occurred >3 billion years ago. Such a confirmation would have to include detailed
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analyses of a variety o f local country rock samples and unusual P G E - r i c h occurrences, such as the B o n A c c o r d body (Tredoux et al. 1989b). M a n y open questions remain and should be addressed in further studies.
Fig. 3.7.1.3. Photographs of a thin section of the Monteville spherule layer (Transvaal Supergroup, South Africa). a) Overview of the spherule layer sample; width of image about 20 mm, crossed polarizers, b) Backscattered electron image of a group of spherules, showing the cores. The mineralogical composition of the spherules and the matrix is similar and indicates pervasive alteration. Scale bar on bottom is 1 mm wide.
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Other occurrences of unusual spherule layers were reported by Simonson (1992) from the Hamersley Basin in Western Australia. This author described spherules that are, on average, about 0.5 to 1 m m in diameter, which consist mainly of K-feldspar, have mostly spherulitic, vesicular, and other crystalline textures, and occur as a stratigraphic marker in the 2.6 Ga Wittenoom Formation. On the basis of similarities to microtektites and microkrystites, Simonson (1992) interpreted the spherules as having formed in an impact even and having been redeposited in a sediment gravity flow. Later, three additional spherule-bearing layers were found in the Hamersley Basin sequence, which were also interpreted to be of impact origin (e.g., Simonson et al. 1997; 1998). Radiometric ages of 2541 +t 8/-15 M a and 2548 +26/-29 Ma have been obtained directly on carbonates associated with two of these layers (cf. Simonson et al. 1998). None of these spherules are associated to with shocked minerals (Simonson and Davies 1996). The absence o f shocked quartz led Simonson et al. (1998) to suggest that the spherule beds formed from an impact into an oceanic target, where quartz is not a major component. On the other hand, shock-characteristic planar deformation features develop in all rock-forming minerals, which would include those that make up oceanic crust. Simonson et al. (1998) found that the Hamersley Basin spherule layers show enrichments in the platinum-group elements (up to 1.7 ppb Ir), but that the interelement ratios are non-chondritic, probably as the result of low-temperature redistribution processes, similar to what has been observed for the distal impact ejecta from the Acraman impact structure in Australia. Simonson et al. (1997) also reported on the discovery of similar spherule layer in the Monteville Formation of the Transvaal Supergroup in South Africa (Fig. 3.7.1.3a, b), which might be correlated with one of the Australian layers. In South Africa, Simonson et al. (1997) found spherules at a constant stratigraphic level in cores from two sites (the Pering mine and the Kathu core) and in surface exposures at two additional sites (Monteville farm and SW of Douglas) over an area of more than 10,000 km 2. The South African as well as the Australian layers contain abundant millimeter-size spherules that consist largely of Kfeldspar, are locally replaced destructively by carbonate, and display external shapes and internal radiating fibrous textures similar to impact-derived spherules from, e.g., the Late Eocene microkrystite strewn field (Sect. 3.3). Thin tuff beds are present in the same stratigraphic succession as the spherule layer and contain millimeter-sized spheroidal clasts. However, these spherules display finely clastic textures and crude concentric layering diagnostic of accretionary lapilli. The Monteville spherule layer is similar in age to the Australian layers; tufts in the general stratigraphic vicinity of the spherule horizon in the Griqualand West succession yielded dates of about 2.55 Ga (cf. Simonson et al. 1997). Recently, Koebert et al. (1999b) found that the Montevilte spherule layer is associated with elevated siderophile element abundances (Table 3.7.1.1). These values are, for Ni up to 167 ppm, Co up to 87 ppm, Cr up to 418 ppm, and, especially, Ir up to 6.4 ppb. No comparable values were measured in any of the other samples, including pyrite-rich country rock or tuffaceous samples. Subsequent analyses showed that the platinum-group element ratios in the spherule layer are roughly chondritic. The
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Table 3.7,1.1. Selected chemical data for some samples from the Monteville spherule layer (Pering Mine), South Africa (from Koeberl et al. 1999b). Pll-IA SL
PII-IB SL
Pll-IB1 SL
P9-1A SL
P11-27B Tuff
Pll-31 SFf
SiO2 TiO2 AI203 Fe203 MnO MgO CaO Na20 K20 P20~ LOI Total
52.5 2.63 24.9 0.55 0.01 3.63 0.35 0.055 11.1 0,07 4.38 100.2
n.d. n.d. n.d. 2.54 n.d. n.d. n.d. 0.069 8.56 n.d. 3.59 99.7
62.5 1.63 17.3 6.68 0.03 1.88 1.76 0.051 6.29 0.04 3.88 100.1
57.9 2.36 20.5 0.55 0.04 2.42 0.88 0.095 11.5 0.05 21.35 100.1
32.1 1.09 8.92 8.16 0.77 7.37 13.6 0.064 6.55 0.20 4.30 99.7
58.8 1.35 14.4 6.76 0.06 2.74 0.62 0.11 10.3 0.14 n.d.
Sc V Cr Co Ni Zn Ga As Se Sb Cs Hf Ir (ppb) Au (ppb) Th
40.6 545 385 2.39 15 30 6.8 0.39 0.75 0.049 7.38 5.17 2.5 4.1 4.22
23.5 293 264 42.7 68 640 6.2 8.98 0.72 0.95 4.92 8.83 6.4 3.9 5.03
20.3 n.d. 180 87.1 167 200 26 21.9 0.91 1.45 3.51 12.6 5.6 8 5.93
13.2 378 418 17.1 65 650 9 1.93 0.29 0.38 19.1 5.38 4.8 1.2 5.63
22.7 160 104 21.2 49 592 52 4.89 0.47 0.33 2.14 2.45 0.6 6.1 1.35
21.2 177 152 16.7 99 124 12 7.59 0.42 0.61 14.6 5.43 <1 5.3 6.85
All Fe as FezO¢ major elements in wt.%, trace elements in ppm, except as noted. SL = spherule layer, S/T = shale with tuff. Samples P11-1A, -1B, -1B l, and P9-1A are spherule layer samples, while P11-2B and -3B are carbonate beds immediately in contact with the spherule layer.
P G E abundance levels in these spherules are c o m p a r a b l e to those found in " n o r m a l " impactites and ejecta and indicate the presence of about 1% by w e i g h t of a chondritic component. N o n e o f the tuff layers show enhanced P G E contents. The high siderophile e l e m e n t contents in the M o n t e v i l l e spherules do not correlate directly with abundances o f s o m e chalcophile elements (Table3.7.1.1), and, unlike in the disputed Barberton M o u n t a i n L a n d spherule layers, are not hosted by secondary sulfides. H o w e v e r , all in all the identification of Precambrian impact deposits (especially distal ejecta) remains a largely unresolved problem. Untbrtunately, so far no definitive criteria for the identification o f A r c h e a n impact deposits are k n o w n (cf, W e i b l e n and Schultz 1978). For none of the South African (Barberton and
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Monteville) or Australian spherule layers has a source crater been found; given the scarcity of the geological record it is likely that it will never be found [if all these layers are indeed the result of impact events and sources craters exist(ed)]. It is not clear why impact events in the Archean would predominantly produce large volumes of spherules, which are mostly absent from post-Archean impact deposits (i.e., those for which source craters are known). On the other hand, none of these spherule layers is associated with any shocked minerals, which are the hallmark for all confirmed impact structures and ejecta. Even rocks from the 2 Ga Vredefort impact structure contain abundant shocked minerals, so it is unlikely that Archean impacts would, for some reason, not produce shocked minerals. Related to this topic is the suggestion by (for example) Rhodes (1975) that the Bushveld Complex in South Africa, a huge igneous province, was formed by multiple impacts. However, French (1990b), Buchanan and Reimold (1998), and Buchanan et al. (1999) did not find any evidence to support this contention. The question regarding how to identify Archean impact deposits remains open and will hopefully be addressed in future studies.
3.7.2 Late Devonian Impact Layer and Alamo Breccia The Frasnian-Famennian (F/F) boundary in the Late Devonian is associated with one of the five largest mass extinctions in the geological record. Glassy spherules, probably similar to microtektites, have been discovered in Late Devonian sections in south China slightly above the F/F boundary (e.g., Wang 1992) and also in Belgium (e.g., Claeys et al. 1992; Claeys and Casier 1994). The spherules have all the characteristics of having formed by impact (Claeys et al. 1992; Wang 1992). In China and Australia the spherule layer seems to be correlated with a minor Ir anomaly (e.g., Playford et al. 1984), which could not be confirmed for the Belgian sections (Claeys et al. 1996). It is possible that the spherule layers in China and in Belgium do not belong to precisely the same layer, as conodont stratigraphy indicates a slight time difference, but this has not yet been confirmed. No source crater for the distal impact layer(s) has yet been identified, although the 54 km diameter Siljan impact structure in Sweden is of similar age. However, this structure may be too small to cause any mass extinctions; at any rate, the relation between the microtektite layer(s) and the F/F mass extinction has not been explored in any detail. Wang et al. (1991) presented evidence for a catastrophic biotic event at the F/F boundary, maybe associated with the impact spherules (Wang and Chatterton 1993), but Racki (1999) concludes that impacts had no distinct influence on the F/F mass extinctions.
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Fig. 3.7.2.1. Alamo Breccia at the Hancock Summit location, showing the chaotic nature of the megabreccia and the large variation in clast size, with mainly small clasts being visible in the photograph. Long dimension of the card at center is about 10 cm.
There is evidence for another large impact event in the Late Devonian. A largescale impact event, dated from conodont stratigraphy at about 367 Ma, occurred in a nearshore marine setting, and resulted in the deposition of the spectacular Alamo Breccia in Nevada (e.g., Warme and Sandberg 1996; Warme and Kuehner 1998). This megabeccia is composed predominantly of limestone with minor dolostone and rare quartzite (Fig. 3.7.2.1). It was found to contain rare shocked quartz with multiple sets of PDFs (Leroux et al. 1995), altered spherules, and possibly an Ir anomaly, and is spread discontinuously over a semi-circular zone of about 200 km diameter and has a total thickness of more than 100 m in some locations. The breccia show a variation in lithology and thickness as a function of increasing distance from the inferred center; no crater has yet been found. It may have been destroyed in (unrelated) post-impact tectonic activity and, thus, is no longer present. The breccia seems to represent both, direct impact ejecta and redistributed tsunami deposits. As the diameter of the source crater is not known, it is not clear if the Alamo Breccia consists of proximal or distal ejecta, but the former is more likely. The age of the Alamo event does not seem to coincide with the ages in-
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ferred for the Belgian and Chinese microtektite horizons, being up to 3 Ma older, and the inferred diameter of the source crater (e.g., Warme and Kuehner t998) may be too small to cause global effects. On the other hand, Morrow et al. (1998) suggested, based on observations of possibly also impact-related megabreccias in Western Europe, that the Alamo event may only have been one of several impact events in the Late Devonian, all of which led to environmental stress and a collapse of the ecosystem that culminated in the F ~ mass extinction.
3.7.3 Permian-Triassic Boundary The Permian-Triassic (P/Tr) boundary (Fig. 3.7.3.1) is associated with the largest mass extinction known in Earth history, during which about 85% of all living species went extinct (Erwin 1994). Following the association of the KfF boundary mass extinction with a large impact event, speculations bloomed that other major mass extinctions might also be related to impact events. However, so far the evidence in favor of such a proposal is controversial. Holser and Margaritz (1992) provided an instructive comparison between the K/T and P/Tr boundary events. The P/Tr boundary is marked by a distinct and sudden drop in the carbon isotopic ratio. Siderophile element anomalies (e.g., enhanced Ir contents) were found at some P/Tr boundary locations (e.g., Holser et al. 1989; Xu et al. 1993), but their source is not clear and confirmation of their extraterrestrial nature is still pending. Chai et al. (1992) found some minor Ir enrichments and concluded that an impact may have been involved, but in some cases it was not possible to confirm the PGE enrichments found by other anthors (e.g., Zhou and Kyte 1988; see also Asaro et al. I982; Yin and Tong 1998). Thus, it is presently not clear if the small Ir anomalies found at some locations (e.g., at the Gartnerkofel, Austria, section; Attrep et al. 1991b) have terrestrial or extraterrestrial sources. It might be possible to obtain evidence in one way or another from Os isotopic studies. Recent research, however, succeeded in demonstrating the P/Tr boundary event was a much shorter event than thought before, and that the severe environmental changes that resulted in the mass extinction were brought on within less than a few hundred thousand years (Bowring et al. 1998). In addition to their geochronologic data, these authors also found that at Meishan, China, the negative excursion in the carbon isotopic composition had a duration of less than about 160,000 years, indicating a catastrophic addition of isotopically light carbon. Bowring et al. (1998) suggested that this addition could be the result of the impact of an icy, carbon-rich comet (but also scenarios involving volcanic processes are conceivable). Rampino and Adler (1998) used fossil data to show that the end Permian extinction pulse was very abrupt, with no indication of stepwise extinctions. Retatlack et al. (1998) reported on the possible discovery of shocked quartz grains from P-Tr boundary locations in Australia and Antarctica, but the exact association of the quartzbearing layers with layers that have enhanced Ir contents and with the P-Tr boundary is still unclear. Similarly, the importance of the possible discovery of fullerenes at the P/Tr boundary (Chijiwa et al. 1999) is not resolved. Other re-
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searchers concluded that the P/Tr extinctions have only endogenic causes (e.g., Schopf 1974; Hallam and Wignall 1997). It seems that the data available so far are not complete enough to allow any definitive conclusions regarding the cause of the P/Tr mass extinction, or the possibility of any impact involvement.
Fig. 3.7.3.1. Permo-Triassic boundary section in Sechuan, China, as pointed out by one of the authors (A.M.).
3.7.4 Triassic-Jurassic Boundary The Triassic-Jurassic (TR/J) boundary is marked by yet another major mass extinction, which is listed as one the "big five" extinctions mentioned by Sepkoski (1992) and Rampino and Haggerty (1996). The first evidence for a possible impact component at the TP,/J boundary came from Badjukov et al. (1987), who found possible shocked quartz at a Tp,/J boundary location at Kendelbachgraben in Austria. Later Bice et al. (1992) reported on the discovery of shocked quartz grains from a TR/J boundary location in northern Italy, although the identification of the PDFs has been questioned (e.g., Mossman et al. 1998). A search for shocked quartz at TR/J boundary locations in Nova Scotia (Canada) was negative (Mossman et al. 1998). The 100 km diameter Manicouagan impact structure in
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Quebec has an age that is comparable to that of the TR/J boundary, but currently available dates indicate that with an age of 214 Ma (Hodych and Dunning 1992) it slightly predates the TR/J boundary. Spray et al. (1998) discussed new evidence for a multiple impact event in the Late Triassic, probably slightly predating that TR/J boundary. On the other hand, Kent (1998) disputed the evidence cited by Spray et al. (1998). However, as past experience has shown, it is very difficult to correlate radiometric ages obtained from impact melt rocks with biostratigraphic ages obtained from the sedimentary record, as a correlation between the two records implies the use of the same time scale, which is basically never the case. Thus, confirmation of an impact signature from other TR/J boundaries might be the next step in the investigation of the end-Triassic event.
3.8 Outlook Distal impact ejecta layers are maybe more common in the geologic record than what was assumed before the K/T boundary was shown to be exactly such a layer. During the last 20 years the number of impact structures known on Earth has more than doubled, and it is likely that the ejecta of at least some of them are preserved in the stratigraphic record. Locations with a well-preserved stratigraphic record, such as the Umbria-Marque region in Italy, provide an ideal ground to search for (and study) possible impactoclastic layers (see Chap. 5). Table 3.8.1 gives a list of those distal ejecta layers that have been definitely, or with some degree of certainty linked to source craters.
Table 3.8.1. Distal ejecta layers and source craters Name of Crater (Age in Ma)
Type of Distal Ejecta
Location
Bosumtwi (1.07)
tektites; microtektites
Ivory Coast; eastern equatorial Atlantic Ocean
Ries (15)
tektites
Central Europe (Czech Republic, Germany, Austria) Switzerland
limestone blocks Chesapeake Bay (35)
tektites; microtektites
North America; southern Ocean; possibly worldwide?
Popigai (35)
microkrystites
Pacific and Indian Ocean, Europe; worldwide?
Chicxulub (65)
K/T boundary
worldwide
Manson (74)
Crow Creek Member
South Dakota, Nebraska
Acraman (590)
shocked minerals
Australia
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An interesting aspect is the influence that impact events have had on the very early evolution of the Earth (e.g., Sleep et al. 1989). Planetary scientists assume that the Earth and other planets formed by accretion of smaller objects (planetesimals). Towards the end of the accretion of the Earth, at about 4.55 Ga, it may have been impacted by a Mars-sized body; from the debris of this giant impact event formed the Moon (e.g., Cameron and Benz 1991; Taylor 1993). The material remaining in orbit after accretion of the Moon would have continued to impact onto the Earth for quite some time. Due to later geological activity, no record of this very early bombardment may remain on the surface of the Earth. On the other hand, there is abundant evidence from Apollo rocks that indicates that the Moon was subjected to intense post-accretionary bombardment between about 4.5 and 3.9 billion years ago (e.g., Ryder 1990; Dalrymple and Ryder 1993, 1996). In addition, the lunar highlands show much evidence for isotopic resetting, consistent with a short and intense late heavy bombardment period, around 3.85 _+0.05 Ga (e.g., Tera et al. 1974; Ryder 1990). However, the interpretation of these data in terms of a distinct period of heavy bombardment were disputed by others (e.g., Baldwin 1974; Hartmann 1975), who suggested that the resetting was caused by the tail-end of the decaying late accretionary impact flux. The reason for a peak in the impact flux is not clear, but could be related to the breakup of asteroids in the asteroid belt (e.g., Zappal~t et al. 1998). This heavy bombardment may also have occurred on other terrestrial planets (cf. Wetherilll 1975). No matter what duration and form the bombardment took, at this time the Earth would have been subjected to a significantly larger number of impact events compared to the Moon, as it has a larger diameter and a much stronger gravitational attraction than the Moon. Some Nd isotope data suggested that the Earth's upper mantle had already undergone some differentiation at the time of formation of the oldest rocks preserved on the Earth's surface (Greenland, Canada, Australia); these data could be interpreted to suggest that small amounts of crust had formed prior to 4 billion years ago, but had later been mixed back into the upper mantle. This view has been confirmed by Hf isotope studies on single zircons (Amelin et al. 1999). It is evident that any large-scale early impacts had some influence on the development of the continental crust (Goodwin 1976; Arndt and Chauvel 1991), and it is conceivable that the late heavy bombardment has been responsible for the rehomogenization of the minor amounts of pre-3.85 Ga crust with the upper mantle. Large scale early impact events must have occurred, no matter if there was a significant peak in the impact flux at about 3.8 to 3.9 Ga, or if this was just the time of the end of an enhanced post-accretionary impact flux. The search for any evidence of such early impacts has important implications, as shown by papers in Gilmour and Koeberl (2000). It has been estimated (e.g., Grieve 1980; Frey 1980) that about 200 impact structures >1000 km in diameter formed on Earth between 4.6 and 3.8 billion years ago, which would have covered about 40% of the surface of the Earth. Using the minimum estimate for the cratering frequency, Grieve (1980) calculated that these impact events would have added a cumulative energy of about 1029 J to the Hadean Earth. It is of course possible that the high flux of
154
large impacts led to large-scale melting of the Earth's crust (Grieve and Cintala 1992; Cintala and Grieve 1998), annealing any possible shock effects. In an attempt to investigate if any record of such a late heavy bombardment period on the Earth has been preserved, Koeberl et al. (2000a) performed a petrographical and geochemical study of some of the oldest rocks on Earth, from Isua in Greenland, where there were earlier suggestions of a possible extraterrestrial component (Appel 1979). In this study, an attempt was made to identify any remnant evidence of shock metamorphism in these rocks by petrographical studies, and to use geochemical methods to detect the possible presence of an extraterrestrial component in these rocks, as described by Ryder et al. (2000) (see also Arnold et al. 1998). For the shock metamorphic study, zircon was thought to offer the best chances of success. Koeberl et al. (2000a) found that many of the studied zircon grains from Isua are strongly fractured, and single planar fractures do occur, but never as part of sets; none of the crystals studied shows any evidence of optically visible shock deformation. Several samples of Isua rocks were analyzed for their chemical composition, including the PGE abundances, by neutron activation analysis and ICP-MS. Only a few samples showed somewhat elevated Ir contents (up to about 0.2 ppb) compared to the detection limit, which is similar to the present-day crustal background content (°0.02 ppb). However, the chondritenormalized siderophile element abundance patterns are non-chondritic, which could (after subtraction of an indigenous component) indicate either the presence of a small extraterrestrial component that has been redistributed (as at, for example, the Acraman ejecta; Sect. 3.5), or indicate terrestrial (re)mobilization mechanisms. In absence of any evidence for shock metamorphism, and with ambiguous geochemical signals, no unequivocal conclusions regarding the presence of extraterrestrial matter (as a result of possible late heavy bombardment) in these Isua rocks can be reached. More details on this topic can be found in the review by Ryder et al. (2000) and in papers in Gilmour and Koeberl (2000). The question that seems to arise more and more often is, how is it possible to identify "unusual" impact deposits as being of impact origin. By "unusual" we mean those that do not seem to show clear evidence of shock metamorphism (in the form of shocked minerals) or where any geochemical signal is not obvious. Many different causes for the absence of either of those two signs of impact could be conceived. For example, the search for shocked minerals in the stratigraphic record is similar to the famous search for the needle in the haystack (cf. Schmitz et al. 1994). Also, an impact into a wet target of mostly soft sediments will most likely not produce abundant shocked minerals (e.g., Buchanan et al. 1998). On the other hand, shock lithification of unconsolidated material is possible (Short 1966). The study of experimental craters may provide some background data (see, e.g., Short 1970; Cordier and Gratz 1995), as well as consideration of local shock formation and propagation (e.g., Spray 1999). Another problem is that microscopic shock features are best developed in crystalline rocks. It is still not clear how to verify shock effects in carbonates. There are only a few studies in that direction, for example by Skala and Rohovec (1998), who performed NMR and XRD measurements of shocked limestones. Employing techniques that are not traditionally
155
used for shock studies, such as cathodoluminescence (e.g., Seyedolali et al. 1997), may help as well. A recent controversy involving "unusual" deposits centered on the suggestion by Oberbeck et al. (1993) and Rampino (1994) that most tillite deposits in the geological record may not be glacial deposits, but impact-derived deposits. However, Reimold et al. (1997), in a detailed petrographical search for shock effects among South African fillites, and Huber et at. (2000), in a geochemical search for an extraterrestrial component in these samples, were not able to provide any confirming evidence for the hypothesis that tillites were produced in impact events. Of course this negative finding does not exclude the possibility that some tillite deposits, somewhere in the wold, could represent impact ejecta, as there is a distinct similarity in the lithological characteristics between the two types of deposits. Oblique impacts at low impact angles may play a greater role in the distribution of distal ejecta than previously thought. We mentioned in Chap. 2 that it is very likely that the four known tektite strewn fields are the result of highly oblique impact events. Schultz et al. (1994) described impact glasses from the (highly elongated) Rio Cuarto impact craters, and Schultz et al. (1998) found some other significant (distal?) impact glass deposits in Argentina; so far no source craters are known. More details on the mechanism of oblique impacts are given by (for example) Schultz (1996) and Sugita et al. (1998). Another open question, which will hopefully lead to intense future research, is, how many other geological boundaries and extinction events could be associated with impact events, as already envisioned by Urey (1973), who discussed a possible link between cometary collisions and geological periods. It is of course counterproductive to suddenly assume that all mass extinctions and catastrophes in the geological record are the result of impact events, just as it would be irrational to conclude that impact played no role whatsoever and that all extinctions resulted from sea level changes or continental flood basalt eruptions. The search for evidence of impact at some boundaries has just begun, including (for example), the Late Ordovician mass extinction (Wang et al. 1992, 1993b, Finney et al. 1999, c), the Devonian-Carboniferous boundary (Wang etal. 1993a), or the Cenomanian- Turonian boundary (Monteiro etal. 1998). In general, the connection between impact events and extinction mechanisms is still not clear (e.g., Keller 1986). What is the influence of the crater size and the target material? Some of these questions were discussed by Jansa et al. (1990), Raup (1992), Jansa (1993), and Poag (1997a). Of course it is conceivable that other extraterrestrial events may have influenced the biological evolution on Earth as well. In this respect it is interesting to note that for the first time it was possible to detect some physical indication (in the form of cosmogenic radionuclides) of a nearby supernova explosion in the geological record (Knie et al. 1999). The possibility that there is some periodicity in the cratering record has also received a lot of attention (e.g., Stothers 1993; Alvarez and Muller 1984), based on the finding of a possible periodic signature in the extinction data (Raup and Sepkoski 1984, but see also Baksi 1990). Subsequent analyses failed to find any evidence for a periodicity among the impact crater ages (Grieve et al. 1985, 1988),
156
partly because not enough craters have been dated with a high enough precision (Heisler and Tremaine 1989). If there would really be a periodic signature among the cratering record, the question regarding its cause arises. A variety of proposals have been made, ranging from comet showers (Davis et al. 1984; Hut et al. 1987), the orbital evolution of the sun in the galaxy (Rampino and Stothers 1984), to unknown companion stars of our sun (Alvarez and Muller 1984). It is interesting that recent helium isotope data (see Sects. 3.3 and 5.8.4) support the possibility of comet showers in the geologic past, but without any periodicity implications. The existence of crater chains on some of the large moons of Jupiter (Ganymede and Callisto; Melosh and Schenk 1993) and on the Moon (Melosh and Whittaker 1994) led Rampino and Volk (1996) to suggest that similar events could have happened on Earth. Despite support of this hypothesis by Spray et al. (1998), there may so far not be enough data to confirm or reject this proposal. In a recent paper, Murray (1999) presented arguments based on celestial mechanics to explain the non-random clustering of aphelion distances of long-period comets (which are those that supposedly originate from the spherical Oort cloud around the solar system) by the possible presence of a so-far undiscovered distant planet with a mass several times that of Jupiter. Given the uncertainty in the ages of impact structures, the small number of precisely dated craters, and the apparent lack of a periodicity in the cratering record, it remains open if the existence of such a hypothetical planet or star can be confirmed by geological observations. We have come a long way since Boon and Albritton (1938) presented their first list of possible meteorite craters and since Bucher (1963) disputed the existence of most impact structures on Earth. Today we have realized that impact events have played an important role in the geological evolution of the Earth, from the formation of the Moon (Cameron and Benz 1991; Taylor 1992, 1993) to the mass extinction at the end of the Cretaceous (Glen 1998), and that much can be learnt from the study of impact craters (Shoemaker 1977) and their distal ejecta, as described in the next chapters for Italian occurrences.
4 The Umbria-Marche Sequence
4.1 Tectonic Setting The Umbria-Marche Apennines of northeastern Italy is a foreland fold-and-thrust belt, which was formed in the latest phase of the Alpine-Himalayan orogenesis (Fig. 4.1.1). These mountains are entirely made of marine sedimentary rocks of the so-called Umbria-Marche (U-M) Sequence, which represents a continuous record of the geotectonic evolution of an epeiric sea from the Late Triassic to the Pleistocene. The Late Triassic-Early Jurassic rifting between Europe and Africa, at the time of the opening of the North Atlantic, led to the formation of new oceanic basins ancestral to the present Alpine mountain chains, including the Pennide-Liguride Ocean (Dercourt et al. 1993). This new ocean, perhaps connected with part of the ancient Tethyan Ocean to the east, outlined a northward-pointing promontory of African continental crust, commonly referred to as Adria or the Adriatic Promontory (Channel et al. 1979). This northward-pointing promontory was in many ways similar to the present south-pointing promontory of North America, which forms Florida and the Bahamas (D'Argenio 1970). The Adriatic Promontory was isolated from the input of clastic sediments. As a large and nearly isolated continental passive margin, Adria underwent extensional faulting. Normal faults defined a complex of subsiding blocks leading to an irregular topography of structural highs (horsts) and adjacent depocenters (grabens and/or half-grabens). In cases where shallow water carbonate deposition could keep up with subsidence, and where the faulted blocks where large enough to support productive carbonate platform environments, very thick sequences of shallow water carbonates developed on the Adria's crust; a prominent example is the Central Apennines of the Abruzzo region. In other regions, subsidence and complex block faulting carried the sea floor down, below the photic zone and out of the zone of shallow-water carbonate production. Areas with this history became pelagic basins, such as the U - M basin, and they recorded, with remarkable continuity and completeness, the geologic, biologic and oceanographic evolution of this region (Fig. 4.1.2).
158
!
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Pen~a
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~ Val Marecchia ~,',.',.',.~ gravityflow
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; , , , , , , ; Abruzzo carbonate ~ ' " '~ plalforrn
-~
Umbria-Marche Triassic to Olicjocene
,l----tSY'a"d~"~,~ ~ L = ~ . ~ . =
5t
ten
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I
I
Major thrust and oblique Upper Miocene faults Major thrust and oblique %'--. PliocenetoPieistocene faults
-~
Pliocene to Pleistocene .~ia~
Fig. 4.1.1. Simplified geologic map of the northeastern Apennines. Fault pattern is from Lavecchia et al. (1994).
159
Following regional extensional tectonics from the Triassic to the Paleogene, the U - M Basin experienced an inversion of the tectonic regime in the Miocene, after which sedimentation was mainly controlled by compressional tectonics. At this time in the evolution of the paleobasin, the Apennine structures were formed in an active fold-and-thrust belt by the motion of thrust sheets from the southwest to the northeast (Fig. 4.1.3). The broad, topographically even, sea floor was transformed in a variety of subbasins at different scales. Loading of the crust by the advancing thrust sheets caused isostatic subsidence and formed a broad foredeep which gradually migrated toward the northeast; its position at the present time is marked by the foredeep basin that roughly corresponds to the Adriatic coastline of the Italian peninsula. Smaller synclinal basins were formed on the flanks of rising anticlines, and were carried to the northeast as piggyback basins. Meanwhile, the Miocene flysch facies reached the U - M region, spreading first as sheets of turbidite material across the region, and subsequently as narrow turbidite fingers reaching into the small synclinal basins left between rising anticlines (Centamore et al. 1978). Continuing thrust motion deformed the earlier turbidites, and the interplay of thrusting and turbidite deposition produced an extremely complex sedimentary geometry. The U - M sedimentary sequence can be divided into two main parts: an upper Triassic to lower Miocene carbonate sequence, and a Middle Miocene to Pleistocene siliciclastic sequence (Fig. 4.1.2). The carbonate sequence was deposited during a long time of extensional tectonic regime and it is mainly represented by deep-water, pelagic limestone and marl formations. On the other hand, the U - M siliciclastic sequence is represented by syn- and post-orogenic clastic deposits, including the flysches of the Marnoso-Arenacea and Laga formations, the black shales and evaporites of the Messinian Gessoso-Solfifera Formation, the turbiditic silt and clay of the Colombacci Formation, and finally, by various sandy beach, and molasse deposits representing the ultimate emergence of the Apennine orogen. In this book, we focus our attention on the carbonate sequence of the U - M Basin, which is mainly represented by deep water, fossiliferous, pelagic limestones and, thus may be considered as an excellent recorder of both local and global events for the past 200 Ma of Earth history. In fact, it has been in this sequence exposed near the Medieval city of Gubbio that Alvarez et al. (1980) first discovered the evidence for an extraterrestrial impact at the Cretaceous-Tertiary (K/T) boundary. The detection of a few part per billion (ppb) of the element iridium in the thin clay layer marking the K/T boundary opened the way to two decades of research activity, by a multitude of interdisciplinary earth and planetary scientists throughout the world, on the impact-induced mass extinction that ended the Mesozoic Era and the rule of the dinosaurs on Earth. And it was in this sequence, in the Global Stratotype Section and Point (GSSP) at Massignano, where Farley et al. (1998) discovered the first geochemical evidence for a comet shower through a stratigraphic interval (the terminal Eocene), in which multiple impacts were already reported by a number of researchers worldwide (see Montanari et al. 1993, and references therein).
160
THE UMBRIA-MARCHE SEQUENCE CHRONOSTRATIGRAPHY
UtholOgy
LITHOSTRAT1GRAPHY
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~
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thick bedded limestone
i
dolamite, bit uminou s limestone, anhyddte Black Shale ** impact Bonamlli Level layer Selii Level Serrone Mads W volcaniCash
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~
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1
break-up of platform;
sedimentation
v ~
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)
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C~-30m - : -400 m
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tectonic regime invers=on from extensional to compressional; preflysch and syn-orogenic flysch deposition; Messinian salinity cr;sis
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Fig. 4.1.2
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Triassic-Oligocene
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.,.,
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162
We find it useful to give herein a brief summary on the sedimentological and stratigraphic characteristics of the U - M carbonate sequence, and illustrate the basic environmental conditions in which the signatures of distal impacts may have been preserved here. In fact, besides the well-studied K/T and the Late Eocene records, many other stretches of complete and continuous stratigraphic record exposed in several outcrops throughout the U - M region, were never explored for impact signatures, which, if present, may be correlated with evidence for impacts in coeval sedimentary sequences in other parts of the world, or with well dated impact craters elsewhere. The U - M carbonate sequence represents, therefore, an ideal ground to further the interdisciplinary research on the general issue of extraterrestrial impacts and the role they may have had in the modification of ecologic environments at local and global scales.
4.2 Stratigraphic Framework of the U-M Carbonate Sequence 4.2.1 Triassic-Lower Cretaceous Above the Hercynian metamorphic basement of Adria topped by Middle Triassic continental deposits, the U - M sequence begins with an upper Triassic unit known as the Burano Anhydrite. This unit, exposed only in a few sites near the city of Perugia, and better known from boreholes, is an evaporite sequence with a complex facies geometry and locally it is as much as 1 km thick (Fig. 4.1.2). The Rhaetavicula contorta limestones of the Cetona Formation, exposed in the western part of the Umbrian region, lays stratigraphically above the Burano Anhydrites, and indicate that the evaporitic conditions terminated before the end of the Triassic (Martinis and Pieri, 1962; Ciarapica et al. 1987). The oldest extensively exposed formation of the U - M carbonate sequence is the Hettangian Calcare Massiccio, a carbonate platform unit which is found across the entire area of the northern Apennines. Although evaporitic conditions were not present at this time throughout the basin, the clearly neritic facies of the Calcare Massiccio indicates that the sediment-water interface remained steadily near sea level. A typical thickness of 700 m for this unit implies a subsidence of about 100 m/Ma. Although rapid, this rate is a reduction from the very rapid subsidence in the Late Triassic, which averaged 170 m/Ma. In the Calcare Massiccio there is a clear facies difference between areas that probably represent differential subsidence of faulted blocks. By the mid-Lias, the entire U - M basin had subsided to depths where neritic carbonate deposition was no longer possible, and pelagic sedimentation begun. Throughout the rest of the Jurassic, sediments deposited in the U - M basin show a clear facies difference between deeper basinal facies (grabens) and shallow water seamount facies (horst; see Fig. 4.1.2). These facies variations represent differential subsidence of fault-
163
bounded crustal blocks inherited from the early Liassic extensional tectonic phase (e.g., Bice and Stewart 1985; Alvarez 1989a, b). In basinal areas, the rest of the Jurassic is represented by the "Complete Sequence", which is about 300 m thick, overlaid by the Majolica Formation, which may reach up to 500 m of thickness. The Complete Sequence (Cbrniola, Rosso Ammonitico, Marne a Posidonia, and Diaspri formations) represents areas of greater subsidence rate, and is characterized by limestones often interbedded with radiolarian cherts. Frequent slumps, pebbly mudstones, megabreccias, and turbidites reflect the presence of steep slopes within the basin, which, in turn shows that extensional faulting was still active (e.g., Castellarin et al. 1978; Coltorti and Bosellini 1980; Lowrie and Alvarez 1984; Bice and Stewart 1986; Alvarez 1989a, b). During deposition of the thick, basinal Maiolica formation, these indications of sedimentary and tectonic instability are gradually reduced. By the mid Cretaceous, the deposition of the Selli Level, a regional, 1 m thick, bituminous regional marker bed at the bottom of the Aptian-Albian Marne a Fucoidi Formation (Coccioni et al. 1987), and the uniformity of thickness and facies of these pelagic sediments throughout the U-M region (e.g., Fiet 1998), indicate that differential subsidence was largely terminated and that the sedimentary filling had almost completely levelled out the irregular topography of the paleobasin. In the shallower, seamount areas (Fig. 4.1.2), the Jurassic, from late Pliensbachian time onward is represented by the very thin (50 m maximum) "Condensed Sequence" (Colacicchi et al. 1970; Centamore et al. 1971; Coltorti and Bosellini 1980; Farinacci et al. 1981). The entire Condensed Sequence at Monte Nerone (northwestern Marche) is represented by the Bugarone Formation, which has been divided into five members (Alvarez 1989 a, b). Cecca et al. (1990) demonstrated the presence of a 25 Ma hiatus within the Bugarone, representing the interval from the middle of the Bajocian through the early Kimmeridgian. Above the Bugarone, at Monte Nerone, there is a second major hiatus representing the whole Barriasian-Valanginian time. This is overlaid by the thin (tess than 100 m) seamount version of the Maiolica Formation, lithologically similar to the basinal, up to 500 m thick, Maiolica. In the seamount areas, as in the adjacent deep basins, the regionally uniform Aptian-Atbian Marne a Fucoidi Formation demonstrates the end of active differential subsidence, and the levelling out of the pelagic sedimentary fill throughout the U-M paleobasin.
4.2.2 Upper Cretaceous-Oligocene During this second major episode in the stratigraphic history of the U-M basin, the role of active extensional fanlting and differential block subsidence was greatly reduced. There must have been local, minor episodes of normal fault reactivation, because we do find slump folds and some turbidites, but these are far less conspicuous than in the basinal Jurassic and lower Cretaceous. Moreover, throughout most of the U-M region, the late Cretaceous-Early Tertiary facies
164
virtually lack extraformational reworked material. Evidently the sea floor was essentially levelled across the paleobasin, and, as a result, the facies of a particular stratigraphic unit is uniform throughout the entire region. Only near the margins of the basin, for example, in the Monte C6nero area near the coastal city of Ancona, or in proximity of the Abruzzo region (Central Apennines), where a broad shallow-water platform endured through this time, do the basinal facies change dramatically in this case to a turbidite and slump-rich slope facies, including debris directly derived from eroded carbonate platform sequences (Crescenti et al. 1969; Baldanza et al. 1982; Alvarez et al. 1985; Colacicchi and Baldanza 1986; Monaco et al. 1987). This time of relatively mild synsedimentary tectonism that followed the rather quiet sedimentation of the Aptian-Albian Marne a Fucoidi is represented by the four formations composing the Scaglia sequence (Scaglia Bianca, Scaglia Rossa, Scaglia Variegata, and Scaglia Cinerea; see Fig. 4.1.2). The Italian term Scaglia means "scale" or "flake"; it refers to the thin, tabular stratification of this homogeneous pelagic limestone, often showing dense concoidal and penciling fracture systems, which give the typical scaly aspect to the tectonically disturbed and/or altered rock. The Scaglia Bianca has a gradational contact with the underlying Marne a Fucoidi as the carbonate/clay ratio increases upwards, and interbedded black shales disappear. It is a mostly white biomicritic limestone containing nodular chert, with a reddish-purple member in the middle, and is about 60 m thick. In the upper 20 m of the unit, white limestone layers are interbedded with black, tabular, laminated chert containing recrystallized radiolarian skeletons and silicified planktonic foraminiferal tests. These black cherts are often associated with thin black shale layers. The analysis of the distances between successive black (shale and/or chert) levels shows that they are organized as multiples of 20 cm (20, 40, 60 .... n20), recording, in fact, a Milankovich-type cyclicity (20 ka, 40 ka, 100 ka; Beaudoin et al. 1996). The Scaglia Bianca represents the latest Albian and the Cenomanian, and the uniform thickness and correlative pattern of the black chert beds throughout the paleobasin (Beaudoin et al. 1996), indicate that this was still an essentially quite tectonic time with regionally uniform sedimentation. The top of the Scaglia Bianca has been often considered coincident with the Bonarelli Level (e.g., Montanari et al. 1989), which is a prominent, carbonate-free, regional marker bed about one meter thick, very similar to the Aptian Selli Level, and representing an oceanic anoxic event close to the Cenomanian-Turonian boundary (e.g., Arthur and Premoli Silva 1982; Beaudoin et al. 1996). The Scaglia Rossa Formation represents the time from the Turonian through the Early Eocene. A short distance above the Bonarelli Level, the pelagic limestones of this unit take on a pink color, and oxidizing conditions prevailed in the basin from then on through the rest of Scaglia Rossa time. The Scaglia Rossa can be divided into four members (Fig. 4.1.2). The lower (R1) member is characterized by the presence of red chert beds; it is overlaid by a chert-free, predominantly calcareous member (R2), followed by a Paleocene, chert-free, member (R3) characterized by marly limestones. The K/T boundary has been used to define the
165
boundary between the R2 and R3 members of the Scaglia Rossa. It is recognized by the disappearance of Cretaceous planktonic Foraminifera and calcareous nannofossils, as well as by a white, bleached zone, about 20-30 cm thick, which commonly occurs just below the boundary (Luterbacher and Premoli Silva 1964; Lowrie et al. 1990; Montanari 1991). The upper member of the Scaglia Rossa (R4) is characterized by the renewed appearance of red, nodular chert beds. Compared to the very quiet Scaglia Bianca, the Scaglia Rossa shows an evident increase in syndepositional tectonism. Slump folding is noted in several levels within this unit (Baldanza et al. 1982; Alvarez and Lowrie 1984; Alvarez et al. 1985; Chan et al. 1985; Montanari et al. 1989), and in parts of the basin there are striking occurrences of white calcarenitic turbidites essentially made of reworked, intraformational planktonic foraminiferal tests (Montanari et al. 1989). The Scaglia Variegata Formation represents the transition from the pink limestones and red cherts of the upper Scaglia Rossa to the gray marly limestones of the Scaglia Cinerea Formation. It is characterized by chert-free marly limestone beds of pink, white, and gray color. The lower boundary is marked by the last occurrence of nodular chert (Lowrie et al. 1982; Chanet al. 1985). The top of the Scaglia Variegata is conventionally located at the top of the uppermost reddish interval (e.g., Odin and Montanari 1988; Coccioni et al. 1988; Montanari et al. 1993). This unit represents the Middle Eocene and most of the Late Eocene. Above the Scaglia Variegata, the thick, rather uniform, and apparently more marly Scaglia Cinerea Formation begins. "Cinerea" means ashy in Italian, but refers to the gray color rather than to the several biotite-rich volcanic ashes contained in this unit (e.g., Montanari et al. 1985, 1988b). Synsedimentary disturbances, such as calcareous turbidites made of extraformational, shallow-water debris, commonly occur in the southern Umbria region, in areas close to the margin of the Lazio-Abruzzo carbonate platform (Monaco et al. 1987). Throughout the rest of the U - M region, the Scaglia Cinerea testifies to rather quiet tectonic conditions in the paleobasin following the mild synsedimentary, extensional tectonic phase of the Scaglia Rossa described above, and preceding the onset of the Miocene synorogenic sedimentation. However, the relative abundance of clay in the Scaglia Cinerea is evidence of tectonic events not far away to the west, which were soon to overrun the area of the U - M Basin and bring to a close the long pelagic, carbonate phase of its evolution. The Scaglia Cinerea represents the Late Eocene and the Oligocene, a time during which the siliciclastic turbidites of the Macigno flysch were being deposited in the Tuscan basin to the west (Abbate and Sagri 1970; Valloni and Zuffa 1983). These turbidites were derived from the erosion of the Alps, and their spread into the area of the future Apennines coincided with the beginning of tectonic deformation of the sedimentary cover in the western part of the Apennines. It seems likely that the clay of the Scaglia Cinerea was derived from the clay component of these turbidites in the area just to the southwest.
166
4.2.3 Miocene Following the extensional tectonics of the Triassic-Early Cretaceous and Late Cretaceous-Early Eocene phases, and the relative tectonic quiescence of the Middle Eocene-Oligocene period, the third phase clearly reflects a sedimentation controlled by compressional tectonics. At the beginning of the Miocene, marly deposition of the Scaglia Cinerea was interrupted by a brief return to dominantly limestone deposition. The resulting unit is the Bisciaro, a formation whose geometry and significance are not fully understood despite its excellent integrated stratigraphic characteristics recently determined by a number of authors in several U - M sections (e.g., Amorosi etal. 1994; Montanari etal. 1991; 1997a, b; Coccioni et al. 1997; Deino et al. 1997). The Bisciaro consists of rhythmic interbeds of shales, volcanic ashes, sandy (and sometimes glauconitic) limestones, and very hard, pure biomicritic limestones. The unit ranges in thickness from 20 to 150 m (Guerrera et al. 1986). It has been suggested (Montanari et al. 1991) that the Bisciaro near Gubbio (eastern Umbria) may represent the slight bulging of the basin floor caused by the advancing load of the northeast-moving Apennine thrust sheet. The Bisciaro is overlaid by the Schlier Formation, consisting of a rhythmic sequence of pelagic and hemipelagic marls and marly limestones containing sporadic intercalations of volcanic ashes (Deino et al. 1997; Montanari et al. 1997b). In the western part of the U - M Basin (i.e., the area around Gubbio), the Schlier is a few tens of meters thick and its hemipelagic deposition is interrupted, in the Langhian, by the arrival of syn-orogenic siliciclastic turbidites of the Marnoso Arenacea flysch. On the other hand, in the easternmost part of the region (i.e., Monte C6nero area), the Schlier reaches a total thickness of over 300 m and covers the whole interval from the top of the Burdigalian to the Tortonian-Messinian boundary. This chronostratigraphic boundary roughly coincides to the base of the Gessoso-Solfifera Formation, which starts with the Euxinic Shale unit that marks the beginning of the Messinian salinity crisis of the proto-Mediterranean. The Apennine synorogenic siliciclastic facies arrived in the C6nero area only in the Pliocene. Thus, this area represents a unique situation in the region where the entire Miocene is still represented by an essentially continuous, and complete sequence of pelagic and hemipelagic carbonate rocks, and constitutes an excellent record of local and possibly global paleoecologic events (Montanari et al. 1997b).
5 Impact Stratigraphy in the U-M Sequence
5.1
Searching for Impact Signatures in the Stratigraphic Record The distal ejecta of an impact found in a sedimentary layer, and a biologic event that may be caused by an impact, have to be dated in terms of numerical age (Sect. 1.9) in order to be correlated with a known impact crater. The most reliable way to assign a precise age to a crater is to date its impact melt rock with a radioisotopic method. In fact, the majority of terrestrial impact craters are found on land and are buried or filled by incomplete sequences of continental sediments that do not permit a direct and accurate stratigraphic correlation with marine, fossiliferous sediments. In some other cases, impact craters are filled with marine sediments with a disturbed (i.e., mixed or reworked) paleontological record that is not conducive to precise and accurate numerical dating of the impact event. Marine sedimentary sequences, on the other hand, are dated by interpolation of few radioisotopic ages, obtained from interbedded volcanic ashes in distant sections around the world, and tied to paleontological, geochemical, and geophysical signatures which are assumed to be contemporaneous worldwide. Therefore, the strength of a correlation between an impact signature found in the sedimentary record and an apparently contemporaneous crater is solely based on the accuracy and precision of the geochronologic time scale, and the reliability of the geochronologic date of that crater. Only a small proportion of the 160 or so impact craters known on Earth have precise ages, which allow an accurate correlation with the stratigraphic record. Moreover, the more we go back in geologic time, the poorer is the accuracy of the time scale, and the rarer are continuous and complete sedimentary sections with well defined bio-, magneto-, and chemostratigraphic characteristics. Consequently, for Paleozoic series or older, the geochronologic calibration of chronostratigraphic units is largely imprecise and probably inaccurate. The geochronologic calibration for Mesozoic series and younger is much more precise and accurate, and sedimentary sequences covering this latest span of Earth's history are much more frequently and extensively exposed than are Paleozoic or older sequences.
168
In the general field of research on the role of impacts in the evolution of the Earth's biota, a first-order approach would be to search for impact evidence (i.e., geochemical signatures and/or impact sphemles and shocked minerals) in those stratigraphic intervals where major biotic crises or mass extinctions are known to occur. For the interval between the Permian-Triassic (P/TR) boundary to the Present, the most recently updated diagram of Sepkoski (1996), which reports the percentage of extinctions of marine fossil genera across interstage boundaries, constitutes a good start for this kind of approach (Fig. 5. 1.1). Three major peaks of extinctions occurred in this 250 Ma interval: at the P/TR boundary (68% extinction of the marine animal genera), in the latest Norian (Te,/J boundary; 47% extinction), and at the K/T boundary (48% extinction). Then, there are six other relevant but smaller extinction peaks across the Pliensbachian-Toarcian boundary (P/T boundary; 27% extinction), the Tithonian-Barriasian (Jurassic-Cretaceous, J/K) boundary (32% extinction), the Aptian-Albian (A/A) boundary (18% extinction), the Cenomanian-Turonian (C/T) boundary (28% extinction), the Late Eocene (LE; 16% extinction), and, finally, the Middle/Late Miocene boundary (M/M boundary; 9% extinction). Relatively high levels of extinction percentages are reported also in the mid-upper Jurassic, but no clearly defined peak is present here. According to Sepkoski (1990), these extinction peaks are regularly spaced by intervals of about 26 Ma. Fig. 5.1.1 also reports the temporal distribution of the known terrestrial impact structures with diameters larger than 5 km (Table 1.9.1). The temporal distribution of the impact structures in the past 150 Ma (i.e., from the J/K boundary to the Present) was studied in detail by Montanari et al. (1998), who did not find any significant periodicity by statistical means. The flux of total energy in megaton delivered to the Earth in the past 150 Ma by large impactors is plotted in Fig. 5.1.2. This figure shows that three peaks of extinction, the J/K, K/T, and LE, correlate precisely with major impact events, the almost coeval Morokweng structure (70-100km diameter) and the Mj¢lnir crater (40 km diameter), the Chicxulub structure (about 200 krn diameter), and the coeval Chesapeake and Popigai craters (about 100 km each), respectively. Correlations between impact structures and other extinction peaks in the J/K to Present interval are very week or absent. As for the Permian through Jurassic time interval, only few impact structures are known, and most of them have large age uncertainties. Among these, only Manicouagan (100 km diameter) may possibly be correlated with the TR/J extinction event (Fig. 5.1.1).
Fig. 5.1,1. Impact structures with diameters larger than 5 kin, impact signatures known in the stratigraphic record, and percentages of marine genera extinctions in the past 250 Ma. The marine genera extinction record is from Sepkoski (1996).
169
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31 Gosses Bluff 32 Mjolnir 33 Morokweng 34 Puchezh-Katunki 35 Red Wing 36 Rochechouart 37 Manicouagan 38 Obolon' 39 Saint Martin 40 Araguainha 41 Kursk Fig. 5.1.1
170
Montanari et al. (1998) pointed out that there is an obvious scarcity of impact signatures (iridium anomalies, spherules, shocked minerals, etc.) known at present in the stratigraphic record, compared to the number of large craters on the surface of the Earth (see Fig. 5.1.1). They explained that this "...is mainly due to the fact that the search for signatures such as Ir anomalies, spherules, and shocked minerals, has been mainly focused across those few short stratigraphic intervals where major extinctions are recorded, or which were known to cover the time of major impacts. The work of the stratigrapher searching for a millimetric impact layer in a sedimentary sequence hundreds of meters thick is comparable to the proverbial search for the needle in the haystack".
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Montanari et al. (1998) also stressed that "...the record shown... (i.e., Fig. 5.1.1 and Table 1.9.1 in this work), or any other that can be derived from published compilations such as the one by Grieve et al. (1995), does not represent all the impact events occurred on Earth in the past 150 Ma, but only the few ones that have left their signature on the Earth's surface and have been discovered up to now". These authors, then, explained the reasons that limit the effectiveness of
statistical work on the Earth's impact record, and pointed out the main problems
171
that are encountered in studying the effect of impacts on the evolution of the Earth from the geological and stratigraphic records. "'There are at least three types o f problems which limit the accuracy f o r a detailed statistical study of the impact record through Earth history.(...) A first source f o r analytical inaccuracy lies in the actual incompleteness of the cratering record due to the fact that the Earth's surface is extremely dynamic on a geologic time scale: many craters may have been completely obliterated by erosion or tectonic deformation, or buried under orogens, or subducted under tectonic plates. Moreover, the size vs. frequency relationship of impacts follows approximately a p o w e r law: small events (craters 20 km in diameter or less) are much more frequent than medium size events (20 to 100 km in diameter) which, in turn, are much more frequent than giant impacts producing craters larger than 100 kin. On the other hand, the preservation probability o f impact craters grows with their size: small structures may be erased f r o m the record much more easily than large ones. Consequently, the record in Figure 1 and Table 1 [in Montanari and coauthor's paper] shows an abnormal abundance of medium size craters (averaging 25 km in diameter), and an anomalous scarcity of small size craters which, according to a p o w e r law distribution, should be much more numerous. This observation also suggests that the probability f o r a giant (-100 kin) crater to be obliterated and, thus, unrecorded in the examined time interval is relatively low. Nevertheless, medium or large impact events are the ones that count more in the general study of impact flux and possible cause-and-effect relationship between impacts and biologic crises. Large impacts are those which may leave a world-wide signature in the geologic record, and may have climatic, environmental, and biologic effects on a global scale. A second problem lies in the fact that many impact craters have been discovered recently, at a rate o f approximately 1-2 new ones p e r year. This is due to the fact that on Earth there are large areas that have not yet been thoroughly explored f o r impact structures. Moreover, about 2/3 of the Earth's surface is made o f oceanic crust, and at present all the known impact craters are located on continental crust... Finally, there are still basic geochronologic uncertainties in the age estimate of impact craters.(...) For instance, f o r a long time the medium size Manson crater was believed to have an age close to the K / T boundary (i.e., about 66 Ma; Hartung et al. 1990). Recently, the melt rock of this crater has been re-dated yielding an age about 8 Ma older (Izen et al. I993; Zeitler 1996). Similarly the Kamensk, another medium size crater (see Table 1 [in Montanari and co-author's paper]) was f o r long time considered a K / T boundary event and only recently was it re-dated at 49.2 Ma (i.e., 16 Ma younger; Izett et al. 1994). Another relevant case is the K a r a - U s t Kara double structure, which was dated by a Russian team using the traditional K/Ar technique at around 66 Ma (Kolesnikov et al. 1988), and in an American geochronology laboratory using the 4°Ar,/gAr technique at about 74 Ma (Koeberl et al. 1990). Further geochronologic dating by Trieloff et al. (1992) led to an age estimate between 69 and 71 Ma. A compromise (conservative) age o f 73 +_3 Ma was finally suggested by Grieve et al. (1995) and is the one we use in this paper.
(from Montanari et al. 1998) Considering all these uncertainties and problems, the U - M carbonate sequence appears a rare opportunity to approach the search for impact signatures in a stratigraphic and sedimentary framework which is remarkably continuous and complete. In the following chapters of this book, we describe the stratigraphic details of outcrops in the U - M region that record major biologic crises that are possibly linked to extraterrestrial events. For those instances where impact signatures have
172
been found, like the K/T and the LE events, we illustrate the impact signatures in detail (i.e., geochemical anomalies, sphernles, shock metamorphosed minerals, etc.). For the other potentially interesting intervals, in which impact signatures have yet to be found, but which may correlate with extinction peaks and/or large known craters, we limit ourselves to a description of the stratigraphy commenting on the completeness and significance of the paleontological record. The next chapter of this book is presented as a state of the knowledge on the impact stratigraphy in the U - M sequence, and at the same time as a sort of guide book for this special geologic region, which will hopefully encourage further research on the fascinating subject of extraterrestrial impacts as possible controlling factors in the evolution of life on Earth.
5.2 The TR/J Record Three closely spaced shale levels containing probable shocked quartz were found by Bice et al. (1992) in the uppermost R h a e t a v i c u l a c o n t o r t a unit near Corfino in northern Tuscany, just below the lithostratigraphic boundary with the overlying Calcare Massiccio Formation, which represents the Triassic-Jurassic (TR/J) boundary. Although no further paleoecologic, paleontologic, petrographic or geochemical research has been carried out at this particular outcrop after the discovery by Bice and co-workers, recent studies on the terminal Triassic record (see Sect. 3.7.4) indicate that the Earth may have been struck by several impacts (Spray et al. 1998), at a time coinciding with a prominent mass extinction peak of marine organisms comparable with that of the K/T boundary (Sepkoski 1996; see Fig. 5.1.1). Thus, the TR/J boundary is definitively an interesting interval for investigating the possible relationship between impacts and mass extinctions. The sedimentology and biostratigraphy of the R h a e t a v i c u l a c o n t o r t a limestone have been studied in several sections of the Northern Apennines, most of which are located in Tuscany (e.g., Ciarapica etal. 1987; Cirilli etal. 1994). Unfortunately, only a few exposures of this unit are known at present in the U - M Apennines. The best documented of them is the Monte Cerchio section, in the Monti Martani area near Spoleto (southern Umbria; see Fig. 4.1), which is exposed along a mountain dirt road between the villages of Terzo San Severo and Massa Martana (Fig. 5.2.1). The lithostratigraphy and the biostratigraphy based on palynomorphs and benthic foraminifers have been worked out, in this section, by Cirilli et al. (1994). However, the stratigraphic data available today from this and other Umbrian TR/J boundary exposures are still too scarce to attempt any inference on the response of the local marine fauna and flora to the extraterrestrial multiple impacts proposed by Spray et al. (1998). One of the main problems is the inaccuracy of biostratigraphic tools for drawing correlations, especially in a basin with marked lateral variations of sedimentary facies and ecologic environments.
173
Fig. 5.2.1. Location map of the Monte Cerchio section covering the Triassic-Jurassic boundary.
One of us (A.M.) visited the Monte Cerchio section just before writing this chapter and realized that, despite the fair continuity of exposure, this outcrop is not quite suitable for the kind of high-resolution stratigraphical study necessary for pinpointing thin impactoclastic layers, such as those studied by Bice et al. (1992) in the Corfino section of Tuscany. The dolomitic limestones are fractured, and the bedding interfaces strongly sheared by tectonic deformation, especially near the contact between the Rhaetavicula contorta limestone and the overlying Calcare Massiccio Formation. Further research in the Triassic terrains of the Urnbrian Apennines will hopefully yield, in the near future, better sections suitable for high-resolution impact stratigraphical studies.
5.3 The Pliensbachian-Toarcian boundary at Valdorbia According to Sepkoski (1996), an extinction peak of marine genera occurs at the boundary between the Pliensbachian and the Toarcian stages (see Fig. 5.1.1). In the time scale of Gradstein et al. (1994), this boundary is dated at 189.6 _+4.0 Ma. The large uncertainty in the age assignment for this interstage boundary, which is about the same for all the interstage boundaries of the Early and Middle Jurassic, may be an impediment in the eventual correlation of geochemical and/or mineralogical signatures to a large impact. However, no large impact craters are known
174
in this interval of geologic time and, thus, there is no hint in the geologic record that the Sepkoski (1996) peak across the P/T boundary is linked to an impact.
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Fig. 5.3.1. Location map of the Pliensbachian-Toarcian section at Valdorb]a.
The Toarcian stage in the U - M Basin is almost entirely represented by a unit called the Marne del Serrone, locally found between the SinemurianPliensbachian Ctrniola Formation, and the upper Toarchian-lower Aalenian Rosso Ammonitico Formation (see Fig. 4.1.2). This unit is characterized by several horizons of black shales interbedded with clays and marls. This Toarcian anoxic event was recognized in other localities throughout the Tethyan domain (e.g., Pettinelli et al. 1995), as well as in Ethiopia (Canuti et al. 1983), and it has been attributed to a marine transgression over epicontinental areas (Hallam 1988; Haq et al. 1988). A biotic crisis associated with this event is probably the main
175
factor making up Sepkoski's extinction peak, but at the current state of knowledge, this interesting event can only be attributed to global variations of sea level in a rifting geodynamic environment such as the U - M paleobasin. One of the best sections to observe the P/T transition and the Marne del Serrone unit in the U - M region, besides the type locality at Monte Serrone, is located near the village of Valdorb~a, along the Arceviese road between the towns of Sassoferrato and Scheggia, and about 2 km east from the latter (Fig. 5.3.1). The main exposure is located within the yard of a mineral water plant (Fig. 5.3.2), but other stretches of the sequence are exposed in the immediate vicinity along the main road and the river, which flows at the bottom of the Gola del Corno valley.
Fig. 5.3.2, The exposure of the Marne del Serrone Formation at the Water Plant near Valdorb)a.
The stratigraphy of the Valdorb]a composite section, which can be correlated with other equivalent sections throughout the U - M basin (Bartolini et al. 1992), was worked out in detail by Monaco et al. (1994) and Parisi et al. (1996). A stratigraphic synthesis of this section is shown in Fig. 5.3.3.
176
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177
5.4 The J/K Record The fourth largest peak in Sepkoski (1996) diagram, with 32% extinction of marine fossil genera, is plotted at the Tithonian-Berriasian boundary (i.e., the J/K boundary). This event is associated with a minor decline in global diversity from one stage to the next although detailed quantitative micro- and macropaleontologic analyses are needed for a better local description of this event (Sepkoski 1996). Nevertheless, in the context of a possible cause and effect relationship between impacts and biotic crisis, the J/K transition is certainly an interesting one, because it covers the time of three large impacts (see Sect. 3.6): Morokweng (>70 km, maybe even up to 200 km in diameter), Mj¢lnir (40 km in diameter), and Gosses Bluff (22 kin in diameter).
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178
One of the best exposures of the J/K boundary in the U-M region is located along a road cut in the Bosso Gorge, near the town of Cagli (Fig. 5.4.1). The boundary is found in the lowermost part of the Maiolica Formation, which has a short, transitional lower contact with the underlying Diaspri Formation. The Diaspri is characterized by thin bedded, variegated (green, red, gray), radiolarianrich cherts and cherty limestones, whereas the Maiolica is a typically white, medium-thick bedded, biomicritic limestone interbedded with, or containing, gray and whitish nodular cherts (Fig. 5.4.2).
Fig. 5.4.2. Panoramic view of the boundary between the Diaspri (D) and the Maiolica (M) formations in the Bosso section.
The biostratigraphy based on calcareous nannofossils and calpionellids, and the magnetostratigraphy of this section (Fig. 5.4.3), were determined by Bralower et al. (1989). Although there is no internationally accepted definition for this chronostratigraphic boundary, the top of ammonite zone Berriasella jacobi was proposed to approximate the boundary, and was correlated to the base of magnetic polarity zone M18r (Ogg and Lowrie 1986). In contrast, in the time scale of Gradstein et al. (1994), the J/K boundary is placed near the base of the B. jacobyi Zone, in the upper part of magnetic polarity zone M19n. In the Bosso section, which contains no ammonites, this stratigraphic level corresponds to the top of
179
calpionellid A3 Zone (i.e., top of Calpionella brevis), with an assigned age of 144.0 _+2.6 Ma according to the time scale of Gradstein et al. (1995).
J!UlOlltt i
gnl8 sasso9 6ue#alOJOl/M
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Fig. 5.4.3. Stratigraphic synthesis of the Jurassic-Cretaceous boundary in the Bosso section.
180
At the current state of knowledge, there seems to be no evidence for biotic crises in the calpionellid and calcareous nannofossil records through the lower part of the Maiolica Formation at Bosso. However, the lithofacies contrast between the Diaspri and the Maiolica formations is sharp enough to envision a major environmental change in this basin, which might correspond, indeed, to a significant explosion of the marine calcareous plankton. Despite the age uncertainties of this portion of the time scale (i.e., _+ 2.6 Ma), and the age imprecision of the Morokweng giant impact (_+ 1.9 Ma; Koeberl et al. 1997c), the stratigraphic interval across the Diaspri-Maiolica boundary, which roughly corresponds to the transition between the Jurassic and the Cretaceous periods, may be regarded as an excellent situation for future high-resolution interdisciplinary stratigraphic studies, including a systematic search for distal impact ejecta possibly delivered by the Morokweng impact event (cf. Kudielka et al. 1999).
Fig. 5.5.1. Location map of the stratigraphic sections in the Bottaccione Gorge and the Contessa Valley near Gubbio. CH = Contessa Highway section; CB = Contessa Barbetti section; CQ = Contessa Quarry section; CR = Contessa Road section.
181
5.5 The Upper Aptian Event An event of diversity decline in early planktonic Foraminifera during the latest Aptian-earliest Albian time was recognized by Leckie (1989). This event, which constitutes a minor extinction peak in Sepkoski's diagram (18 % of marine genera; see Fig. 5.1.1), was attributed to widespread episodic production of warm, saline water masses in numerous, relatively isolated, marginal basins, and/or in subtropical oceanic areas (Leckie 1989). In the U - M sequence, this event is well recorded in the Brown Clay Member of the Marne a Fucoidi Formation, within the planktonic foraminiferal Hedbergella planispira Zone (Coccioni et al. 1987). The Marne a Fucoidi Formation (see general description in Sect. 5.1) is extensively exposed throughout the U - M region. Its stratigraphy has been studied in detail by a number of researchers in several sections and in a core drilled near Piobbico (e.g., Arthur and Fischer 1977; Herbert and Fischer 1986; Coccioni et al. 1987; Premoli Silva et al. 1989; Erba 1988 and 1992; Fisher et al. 1991; Fiet 1998). Excellent and well documented outcrops are found in the classic area of Gubbio, namely in the Bottaccione Gorge and in the Contessa Valley (Fig. 5.5.1). The most spectacular exposure of the stratigraphic interval covering the upper part of the Maiolica, the Marne a Fucoidi, the Scaglia Bianca, and the lowermost Scaglia Rossa, is located in the Vispi quarry, on the east slope of the Contessa Valley (see location map in Fig. 5.5.1, and panoramic view in Fig. 5.5.2). Here the contact between the Maiolica and the overlying Marne a Fucoidi, which corresponds roughly to the Barremian-Aptian boundary, is disturbed by a conspicuous soft-sediment slump representing the last major episode of instability in the Jurassic-Early Cretaceous extensional tectonic phase in this area. Similar slumps at the same stratigraphic level are recognized in numerous other sections throughout the U - M region (Coccioni et al. 1987). At Contessa, the bituminousradiolaritic-ichthyiolitic Selli Level, which marks the boundary between the Maiolica and the Marne a Fucoidi (Coccioni et al. 1990), is clearly recognizable in the slump-deformed zone (Fig.5.5.2). At Contessa, the Brown Clay Member of the Marne a Fucoidi Formation, which contains the Aptian-Albian boundary, is well exposed on the Vispi quarry face. However, the best and most studied exposure of this interval in the U - M region is located above a dirt road at the foot of the Poggio Le Guaine peak (see road map in Fig. 5.4.1 and panoramic view in Fig. 5.5.3). Although the detailed foraminiferal stratigraphy of this section by Coccioni et al. (1990) allows a precise location of the Aptian-Albian boundary (Fig. 5.5.4), and a fairly precise numerical age assignment using the Gradstein et al. (1994) time scale (i.e., 112.2 _+ 1.1 Ma), no large craters are known with this age, and, to our knowledge, no detailed studies were ever carried out in this section, or in any other sections, that focussed on the search for impact signatures. Therefore, the A/A extinction peak remains a complete incognita in the general study of biotic crises possibly caused by impact.
182
Fig. 5.5.2. Panoramic view of the Vispi quarry in the Contessa Valley, exposing the U - M pelagic sequence from the Maiolica to the Scaglia Rossa. Note the conspicuous slump near the Maiolica-Marne a Fucoidi boundary. MA = Maiolica; SEL = Selli Level; MF = Marne a Fucoidi; SB = Scaglia Bianca; SR = Scaglia Rossa.
J;
L
Fig. 5.5.3. Panoramic view of the Poggio Le Guaine section. The Brown Clay Member containing the Aptian-Albian boundary is exposed at the base of the outcrop.
183
POGGIO LE GUAINE LITHOSTRATIGRAPHY
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Lithology
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Fig. 5.5.4. Stratigraphic synthesis of the Poggio le Guaine section (after Coccioni et al. 1990).
184
5.6 The Cenomanian-Turonian Boundary A prominent extinction peak in Sepkoski's (1996) diagram (26% marine genera) is placed at the Cenomanian-Turonian boundary, and corresponds to the so-called Bonarelli Oceanic Anoxic Event. The Bonarelli Level is a carbonate-free, regional marker horizon, about 100 +40 cm thick, very similar to the Selli horizon described in the previous section of this book, and it is often used as boundary marker between the Scaglia Bianca and the Scaglia Rossa formations (Figs. 4.2 and 5.5.2). It is made of an alternation of dark radiolarites and black hychtiolitic, bituminous shales (e.g., Arthur and Premoli Silva 1982; Van Graas et al. 1983; Piergiovanni 1989; Marcucci et al. 1991), and although its total thickness varies laterally, its internal stratigraphy is remarkably consistent throughout the region (Montanari 1979, M'Ban 1994; Beaudoin et al. 1996). The C/T boundary event is one of the most thoroughly studied mass extinctions of the Phanerozoic, and is extensively exposed in numerous excellent sections, especially in North America and Europe. So much has been written about the C/T boundary that it would be impossible to cite and comment here the copious literature on this subject, properly honoring all the authors who invested so much effort in studying and interpreting the complex patterns of stepped extinctions, survival, and recovery of marine organisms in stressed paleoenvironments during this critical interval of Earth history. Nevertheless, for general and well-referenced reviews of the C/T boundary, we would like to cite the recent works of Harries and Kaufmann (1990), Peryt and Lamolda (1996), Tur (1996), Hart (1996), and Fitzpatric (1996), as well as the thorough synthesis, and the references therein, in Hallam and Wignall (1997). The cause of the extinctions across the C/T boundary is accepted by most authors to be related to a peak in high sea level stand and the onset of widespread dysoxic and locally anoxic conditions (i.e., the Bonarelli Level) throughout the world's oceans. Although such an eustatic event affected primarily shallow water environments and carbonate reefs, the expansion of the 02 minimum zone had a serious toll also in the open ocean realm, and both benthic and planktonic foraminiferal communities, among other oceanic microorganisms, suffered extinctions and turnovers. The extinction of the planktonic foraminiferal genus Rotalipora in the latest Cenomanian (i.e., R. cushmani Zone), for instance, reflects the onset of a crisis in the mid-water column of the open marine environment. Along with Ritalipora, also the genera Praeglobotruncana and Dicarinella, which appeared in the late Cenomanian, temporarily disappeared through the C/T transition, and then reappeared in the early Turonian (Leckie 1989). An extraterrestrial cause for the C/T environmental crisis and mass extinction did not find much support in any of the detailed studies carried out by a number of researchers throughout the world. First of all, no large craters are known with an age comparable to that of this stratigraphic boundary (i.e., 93.5 -+ 0.2 Ma in the time scale of Gradstein et al. 1994), except for the Steen River structure in Canada
185
which, in any case, has a modest diameter of 25 km, and an imprecise K/Ar age of 95 _+7 Ma (Carrigy 1968). Multiple impacts as a cause for a global climatic deterioration around the C/T boundary were proposed by Hut et al. (1987) on the basis of two small iridium anomalies (0.11 ppb over a background of about 0.02 ppb) detected by Orth et al. (1988) at the top of R. cusmani Zone in a section near Pueblo, in Colorado. Similar anomalies were then detected in other sections throughout the western interior of the United States (Orth et al. 1990). Although these authors did not preclude an (oceanic) impact source for these anomalies, the absence of impact spherules and shocked minerals in the Ir-rich layers, and the overall mafic proportions of other trace elements in the same layers, led them to suppose that these Ir enrichments were derived from a particularly active mid-oceanic ridge volcanism in the Atlantic at the end of the Cenomanian. Needless to say, the C/T boundary is excellently exposed in numerous outcrops throughout the U - M Apennines. Once again, the Bottaccione Gorge at Gubbio is to be considered the classic site for this boundary and for the Bonarelli Level (Bonarelli 1891). The planktonic foraminiferal biostratigraphy across the boundary is documented in detail by Premoli Silva and Sliter (1995), and the sequence of biozones Rotalipora cushmani-Whiteinella archeocretacea -Helvetoglobotruncana helvetica was recognized by these authors upon closelyspaced sampling and quantitative analyses of thin sections. The W. archeocretacea Zone, which is about 10 m thick (i.e., 1.4 m.y. long), is the one that contains the C/T boundary and the Bonarelli Level. As briefly mentioned in Sect. 4.2.2, the upper member of the Scaglia Bianca is characterized by a rhythmic sequence of white, biomicritic, pelagic limestones interbedded with black, laminated, tabular cherts, and expressing a Milankovichtype cyclicity. The sedimentology, quantitative biostratigraphy, and chemostratigraphy of the Scaglia Bianca has been studied in great detail by M'Ban (1994) in a number of outcrops throughout the U - M Apennines (see also Beaudoin et al. 1996). From an isopach study of the Bonarelli Level and the underlying black cherts of the Scaglia Bianca, Montanari (1979) and M'Ban (1994) reconstructed a slightly undulated sea floor, with relatively depressed areas in the center of the paleobasin (i.e., Furlo basin; see Fig. 4.1.2). Although bland, this slightly irregular topography was effective in controlling the development of pre-Bonarelli anoxic episodes at different times and in different parts of the paleobasin (Beaudoin et al. 1996), as well the first and last occurrences of index fossils, probably due to lateral variation of preservation factors. Among the several C/T outcrops studied by M'Ban (1994) and Beaudoin et al. (1996), the Upper Road at Furlo (Fig. 5.6.1) can be considered as the reference section in this region, as it is the most complete and best exposed (Fig. 5.6.2). The stratigraphy of the Furlo Upper Road section across the C/T boundary is synthetized in Fig. 5.6.3.
186
1 km
Monte Pietralata
Pieb'alata church
upper quar~
S
River
Fig. 5.6.1. Locationmap of the Pietralata and Upper Road sections at Furlo.
The search for impact signatures near the C/T boundary in the U-M Apennines dates back to the earliest development of the theory of impacts as a cause of mass extinctions. However, no evidence for impact has been produced so far. Wezel et al. (1981) reported iridium in samples from the Bonarelli Level at Burano (near Cagli) and Furlo, with anomalously high concentrations between 7.9 and 11.4 ppb. However, the reliability of the results of Wezel and co-workers was strongly questioned by Alvarez et al. (1984), who independently analyzed, by instrumental neutron activation analysis (INAA), a dozen samples covering the whole Bonarelli Level in the Furlo Upper Road section, and found no Ir higher than a best integrated value of 0.00 _+0.03 ppb. Alvarez and co-workers concluded that the high Ir concentrations reported by Wezel et al. (1981) were due to sample and/or laboratory contamination.
187
Fig. 5.6.2. Panoramic view of the Furlo Upper Road outcrop showing the boundary between the Scaglia Bianca and the Scaglia Rossa formationsmarked by the Bonarelli Level.
In 1986, one of us (A.M.) collected some 500 one half inch core samples across the C/T boundary interval in the Furlo Upper Road section, completely covering an interval from 3 m below to 2 m above the Bonarelli Level. In addition, each alternating black shale and radiolarite of the Bonarelli was also collected. These samples were analyzed the following year at the Lawrence Berkeley Laboratory by Frank Asaro with the 1NAA Ir coincident spectrometer, but all proved to be practically bare of iridium. The highest Ir concentration of the whole sample collection was found in a thin black clay lamina at the base of the Bonarelli Level, which showed an insignificant Ir content of 0.05 _+0.02 ppb. These negative, unpublished results, along with the apparent lack of shocked minerals and impact sphernles in several Bonarelli samples analyzed by one of us (A.M.), led the Berkeley team to withdraw from further costly and timeconsuming analyses of the C/T boundary interval in Italy.
188
40
FURLO IMPACT STRUCTURE
30
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Black chert
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Cherty limestone
Fig. 5.6.3. Stratigraphic synthesis of the Scaglia Bianca-Scaglia Rossa transition (i.e., the C/T boundary) in the Furlo Upper Road section.
189
In summary, there is no evidence yet that extraterrestrial impacts had a role in the Cenomanian oceanic anoxic event and related mass extinction. There are no known large impact structures on Earth with a C/T age, and no impactoclastic layer was ever found in the numerous C/T boundary sections studied by a number of researchers in the United States and in Europe. The few minor iridium anomalies found in several North American sections are preferably interpreted as the result of oceanic volcanism. This is enough to discourage anyone in undertaking a focused impact-stratigraphical study on this interval. Nevertheless, the Cenomanian anoxic crisis and the mass extinction documented in the fossil record at the end of this stage is still surrounded by an aura of mystery. That anoxic crises were caused by eustatic sea level changes, which were triggered by global climatic changes, is undoubtedly a reasonable hypothesis strongly supported by an enormous volume of data and observations. Complicated kill mechanisms can be devised or inferred from this hypothesis, such as reorganization and overturning of marine currents and water masses, changes in heat transfer patterns, and oxygen and nutrient redistribution in the oceans, with consequent alteration of delicate equilibria controlling the stability of various environments, and a chain effect of destructions of diverse, more or less interdependent ecosystems (see Hallam and Wignall 1997, for an excellently referenced review of these mechanisms). But the question remains: what caused the climatic change in the first place? This question can be asked for all of the mass extinctions boundary in the Earth history record. Exceptionally active tectonism and related volcanism are certainly earthly factors capable of altering global climate, and constitute the basis for a working hypothesis that the vast majority of earth scientists have no difficulty in accepting as workable and rewarding. On the other hand, the extraterrestrial cause cannot be ruled out a priori, even if up to date there is no convincing evidence for impacts at the C/T boundary. In fact, a comet shower, such as the one predicted by Hut et al. (1987), not necessarily has to produce giant or large impacts that are capable of leaving an impactoclastic signature worldwide. On the other hand, the accretion of a huge volume of interplanetary dust particles during a comet shower, along with a myriad of small cometary impactors, for a period of 2-4 million years (the expected duration of a comet shower) may p e r se be an efficient agent for altering the Earth's atmosphere with consequent rapid climatic and biologic changes. The geologic evidence of a comet shower has been documented, for the first time, by Farley et al. (1998) after the discovery of a significant enhancement of 3He in a 2.5 million year interval across the uppermost Eocene in the Massignano section (see Sect. 5.8.2). Multiple impacts are known to have occurred in the terminal Eocene and at least one impactoclastic layer in the same time interval seems to have a global occurrence (e.g., Montanari et al. 1993), whereas several others have been found at different stratigraphic levels in upper Eocene sediments worldwide. To our knowledge, there has been no specific search for comet shower evidence (i.e., 3HefHe analysis) across the C/T boundary. This stratigraphic interval, with its Bonarelli Level so well exposed and documented in the U - M
190
Apennines, constitutes, therefore, an appealing invitation for further investigations on the possible extraterrestrial role in global environmental and ecologic crises.
5.7 The Terminal Cretaceous Record The uppermost Cretaceous-lower Tertiary Scaglia Rossa Formation of the U - M basin has been the object of numerous interdisciplinary studies in the past decades, which yielded a remarkably complete and detailed picture of its sedimentological setting and tectonic evolution (e.g., Arthur and Fischer 1977; Baldanza et al. 1982; Alvarez et al. 1985; Montanari 1988; Montanari et al. 1989), calcareous plankton biostratigraphy (e.g., Luterbacher and Premoli Silva 1962; Premoli Silva 1977; Monechi 1977; Monechi and Thierstein 1985; Premoli Silva and Sliter 1994), magnetostratigraphy (Alvarez etal. 1977; Roggenthen and Napoleone 1977; Lowrie etal. 1982; Alvarez and Lowrie 1984; Chan et al. 1985), and stable isotope chemostratigraphy (e.g., Renard 1985; Corfield et al. 1991). In this section, we review the state of knowledge of the terminal Cretaceous impact stratigraphy in the U - M sequence. This is a particularly interesting portion of the stratigraphic sequence, because it records the critical time of a major mass extinction (the K/T boundary event), which was preceded by a general deterioration of environmental conditions at a global scale (the Maastrichtian crisis; e.g., Barrera 1994; MacLeod and Huber 1996; Barrera and Savin 1999), especially in shallow marine environments (e.g., Swinburne 1982). Moreover, the end of the Cretaceous Period records three large impact events. Two of them, Kara-Ust Kara and the Manson, occurred in the upper Campanian and the lower Maastrichtian respectively, and the third one, Chicxulub, coincides with, and is very likely the primary cause of, the K/T boundary mass extinction. For a better understanding of the chronostratigraphic framework of this critical interval of Earth history, we propose in Fig. 5.7.1 a stratigraphic synthesis of the upper Campanian to Danian interval in the classic sequence of Gubbio (Bottaccione and Contessa sections; see location maps in Figs. 4.1.1 and 5.5.1), along with the chronologic location of the three aforementioned impact events. We then proceed with the documentation of impact signatures in the Maastrichtian and the K/T boundary events separately.
191
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192
5.7.1 The Maastrichtian During nearly two decades of scientific debate following the Alvarez et al. (1980) hypothesis of a terminal Cretaceous mass extinction caused by an impact event, some three thousand scientific papers have been published on the subject. This enormous volume of printed matter examined the most disparate aspects of this extraordinary event, from astrophysics to paleontology, geochemistry to stratigraphy, mineralogy to paleoecology, and so on (e.g., Glen 1994; Alvarez 1997). Since the very beginning of this scientific ferment, which is unprecedented for any other chronostratigraphic bounda@, one of the strongest objections against the impact-induced mass extinction idea came from the paleontologic community. This critical reaction was, and it is still now for some people, not just a matter of principle or paradigm (i.e., gradualism vs. catastrophism), but it is based on evidence that various ecologic systems and taxonomic groups, especially in shallow water marine environments, were already going through a crisis millions of years before the fatal K/T boundary event. The reef-building rudists, for example, after a radiation in the Late Cretaceous, all but disappeared at the beginning of the late Maastrichtian (e.g., Kauffman 1984; Swinburne 1990; Swinburne and Noacco 1992). A similar trend is observed in the ammonoids and belemnoids, which suffered an accelerated decline through the late Maastrichtian, starting some 4 million years before the K/T boundary (Hallam and Perch Nielsen 1990; Ward et al. 1991). This pre-K/T biotic crisis, which has particularly evident in carbonate platform and shallow water environments, has been attributed to an eustatic sea level drop (e.g,, Swinburne 1990 1992). As for the pelagic realm, the pre-K/T crisis seems much less pronounced. Among deep water organisms, the inoceramids (large bivalves) all disappeared in the mid Maastrichtian, apparently instantaneously in individual basins, but diachronically in distant basins worldwide. A detailed study of the inoceramid extinction in the U - M basin was carried out by Chauris et al. (1998), who, through precise lithostratigraphic and magnetostratigraphic correlations, established that these bivalves at Gubbio and in other U - M sections became suddenly and simultaneously extinct within the upper part of magnetochron 31r, some 0.9 Ma prior to the genus extinction in the Basque Country basin (e.g., MacLeod and Ward 1990). Also in the planktonic foraminiferal realm, a turnover or decline seems to have started already in the mid Maastrichtian (MacLeod 1994). According to this author, the transition between the latest Cretaceous and the basal Tertiary took place at different rates in different basins throughout the world. In the pelagic U - M basin, the pre-K/T decline is documented by Premoli Silva and Sliter (1995) with a detailed and comprehensive study of the planktonic foraminiferal record in the Bottaccione section at Gubbio, and by Chauris et al. (1998), who also studied the relation between the foraminiferal record and the inoceramid extinction in several well-exposed sections throughout the region,
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including Bottaccione. In Fig. 5.7.1.1 we propose a synthesis of the inoceramid, planktonic foraminiferal, and stable isotope records of the classic section of Bottaccione derived from published works. The ~1*O paleotemperature curve of the surface water from Spicer and Corfield (1992) shows two relative minima centered at 73 Ma and 69 Ma, respectively. A relative negative shift of the 513C curve by Renard (1985), which could reflect a period of low primary productivity in this basin, mimics approximately the second interval of relative low paleotemperature. This interval also coincides with a decline in planktonic species diversity, which was quantified by Premoli Silva and Sliter (1995) from the number of originations and extinctions in the overall species count. Two abundance peaks in the inoceramid population occur right within this interval of low temperature, low primary productivity, and low planktonic foraminiferal species diversity (Chauris et al. 1998). The ultimate extinction of the inoceramid is immediately preceded by a significant drop in the relative abundance of bi-keeled planktonic foraminifers, and coincides with a significant negative shift in the 8~3C curve (Chauris et al. 1998). The data synthetized in Fig. 5.7.1.1 from various independent sources strongly indicate that an overall ecologic and environmental deterioration of the open sea realm occurred in the Maastrichtian prior to the K/T boundary catastrophe. The simplest explanation for this apparent pre-K/T crisis is that climatic and eustatic sea-level changes were the primary causes for the observed biologic and geochemical signatures shown in Fig. 5.7.1.1. For the few who are involved in the study on the role of impacts in the evolution of the atmosphere and biosphere, the question goes a step further: could it be that these pre-K/T biologic and environmental changes were caused by extraterrestrial events? A first approach toward answering this question is to look at the available impact record. In the interval across the Campanian-Maastrichtian boundary the record shows, in fact, two large impact structures: Manson (Iowa), and Kara-Ust Kara (Arctic Russia). The Manson crater (see Sect. 3.4) is a buried structure 37 km in diameter, with a precise 4°ArflgAr plateau age of 74.1 + 0.1 Ma (Izett et al. 1998). However, it is a relatively small structure, which could not be considered p e r se as an effective cause for a mass extinction (Jansa et al. 1990). The Kara-Ust Kara structure, on the other hand, has some potential for being a killer, although there are still uncertainties about the actual size and shape of this structure. Originally it has been considered a double impact structure with a diameter for Kara estimated at about 65 km, and a diameter for Ust Kara, which is mostly submerged under the Kara Sea, of about 25 km. Geological studies by Nazarov et al. (1991) suggested a single crater with a diameter between 70 and 155 km, whereas analyses of geophysical profiles by Koeberl et al. (1990) led to a diameter estimate of 80 km for the Ust Kara crater. In our compilation in Table 1.9.1 we have adopted the smallest, most conservative estimates, but this may turn out to be wrong in the future, also considering that Nazarov et al. (1991) argued that there is not enough evidence for two Kara craters, and that it may well be a single, >120 km diameter structure. This latter estimate would make of the Kara the largest known impact structure in Russia.
195
As for the energy flux onto Earth delivered by the combined Kara-Ust Kara double impact, it defines the fourth largest peak in the past 150 Ma record (Montanari et al. 1998; see Fig. 5.1.2). In short, the Kara-Ust Kara structure may be a big enough event to contribute to a global ecologic and environmental change. Coincidentally, it's accurate 4°Ar/39Ar plateau age of 70.3 + 2 . 2 M a (Trieloff et al. 1998) puts it right in the middle of the lower Maastrichtian critical interval marked by low temperature, low primary productivity, and low planktonic foraminiferal species diversity in the pelagic record (Fig. 5.7.1.1). Recent high-resolution studies on the pelagic record of the U - M sequence are revealing new evidence that the Manson and the Kara-Ust Kara impacts may be part of a cosmic crisis that lasted several million years across the CampanianMaastrichtian boundary. Mukhopadhyay et al. (1998) reported an 3He increase in the Scaglia Rossa limestones of the Poggio San Vicino (see location map in Fig. 5.7.6.7) and the Gubbio sections at Bottaccione and Contessa (Fig. 5.5.1), spanning about 4 m.y., with a 3He concentration peak a factor of five higher than average terrestrial values, approximately centered at 70 Ma. A similar 3He anomaly found in the upper Eocene section of Massignano (see Chap. 5.8.4 below) was interpreted by Farley et al. (1998) as evidence for a comet shower, which would have delivered onto Earth an enormous amount of 3Hecarrying interplanetary dust particles (IDPs). During this terminal Eocene time, several impact events are documented (i.e., the 90 km Chesapeake structure at 35.3 + 0.2 Ma; the 100 km Popigai structure at 35.7 +_0.8 Ma; the 28 km Mistastin crater at 38 + 4 Ma; and the 17 km Logoisk crater at 40 + 5 Ma; see Table 1.9.1). This whole cosmic crisis scenario leads to the hypothesis that a large number of small- and medium-size impacts, accompanied by an anomalously high influx of IDPs extending through a period of several million years, have the potential of causing global climatic (and, consequently, ecologic) changes by altering the transparency of the atmosphere, without the need for a giant killer crater the size of the K/T Chicxulub structure. The next critical question in testing the hypothesis that extraterrestrial accretion had a role in the pre-K/T Maastrichtian crisis is, where we search for the distal impactoclastic layers produced by these events in our marine sedimentary sequence? In doing so, we may face the problem of the needle in the haystack. In fact, the Late Eocene Massignano experience, and the finding of an impactoclastic layer with Ir anomaly, impact spherules, shocked quartz, spinels, and 3He (see Sect. 5.8.4), shows that a large impact event the size of Popigai or Chesapeake does not produce a significant lithologic change in a deep marine, carbonate sediment. Unlike the case of the K/T boundary, where a clear break of the carbonate production is marked by a thin but recognizable clay-rich layer worldwide, the upper Eocene impactoclastic level at Massignano is contained within a strongly bioturbated and homogenized marly limestone layer. Only a very subtle color change can be seen there, and the impact spherules are sparse throughout a 510 cm interval of indurated carbonate rock. In the case of the Kara-Ust Kara impact, its age uncertainty of -+ 2.2 Ma would correspond to about 40 m of homogenized, hard limestone layers at Gubbio. The
196
impact signatures may be somewhere in this sequence, but certainly it will require a non-trivial effort to pinpoint their locations. As a first approach in the search of the needle in the haystack, one of us (A.M.) collected three clay layers in the region of the inoceramid event at Contessa. These cm thick layers, located at 297.3 m, 297.8 m, and 301.0 m respectively, are not pressure-solution residual seams, which are the common limestone pseudobedding partings in the Scaglia Rossa Formation (Alvarez et al. 1985). Their continuity and thickness are suggestive of primary sedimentary clay layers, indicating brief interruptions of the biogenic carbonate sedimentation, just like the K/T boundary clay. The washed residues >63 pm of these sample contain numerous shiny, metallic and highly magnetic spherules with diameters between 80 and 150 g m (Fig. 5.7.1.2). Impact spherules? Unfortunately not.
Fig. 5.7.1.2. Magnetic spherules from a clay layer at meter level 297.3 in the Contessa section. These objects, similar in shape to cosmic spherules, are made of pure iron and were probably produced by the exhaust of diesel engines. Thus, they represent a case of recent surficial outcrop contamination. Scale bar = 0.1 ram.
The spherules were analyzed by electron microscopy in Vienna by one of us (C.K.). These spherules turned out to be made of pure iron, which would indicate that they are not of extraterrestrial or impact origin, but rather the products of recent metallurgic industry. This is not the first time that metallic spherules are found as contaminants in soft rocks exposed near busy highways (Montanari 1986), or railroads (Byerly et al. 1990; Eustoquo Molina, personal communica-
197
tion, 1999). This type of spherules may have been produced by the friction of mechanical automotive parts, such as breaks and gears in trucks and locomotives, or, possibly, from the exhaust of diesel engines. The search for the needle continues.
5.7.2 Definition of the K/T Boundary in the U-M Basin With the definition and proposal of the Globigerina eugubina planktonic foraminiferal biozone as the base of the Tertiary (i.e., Paleogene) in the type section of the Bottaccione Gorge, near Gubbio, Luterbacher and Premoli Silva (1964) described in detail a number of other K/T sections throughout the U - M Apennines. In doing so, they established a simple and precise criterion for recognizing the K/T boundary in any pelagic carbonate sequence in the world. In general, the boundary is marked by a thin (0.5-2.5 cm) clay layer sandwiched between the last Cretaceous limestone containing large (up to 1 mm) planktonic foraminifers, such as the Globotruncanidae, Rugoglobigenindae, and Heterohelicidae, which are recognizable with a hand lens, and the first Tertiary limestone containing tiny (less than 0.1 ram) globigerinids not visible with a hand lens (Fig. 5.7.2.1). In the mid 1970s, a renewed interest in the nearly continuous and complete Upper Cretaceous-Paleogene sequence of Gubbio by a group of interdisciplinary researchers lead them to join into a perhaps unprecedented team effort for resolving the lithostratigraphy, sedimentology, planktonic foraminiferal biostratigraphy, and, above all, the magnetostratigraphy of this span of geologic time. The results of this coordinated research project were published in a series of papers in an issue of the Geological Society of America Bulletin (Arthur and Fischer 1977; Premoli Silva 1977; Lowrie and Alvarez 1977; Roggenthen and Napoleone 1977), along with the proposal of Gubbio as type section for the Late Cretaceous-Paleogene geomagnetic reversal time scale (Alvarez et al. 1977). For the first time it was possible to assign accurate biomagnetostratigraphic ages to the marine magnetic anomalies, and, thus, to date, with reliable geologic and biochronologic criteria, the expanding world's oceans. A few years later, the discovery of an iridium anomaly at the K/T boundary of Gubbio, and in other U - M sections, and the proposal of the hypothesis that the impact on the Earth's surface of a large extraterrestrial object was the cause of the terminal Cretaceous mass extinction, was published by Alvarez et al. (1980), opening the way to two decades of extraordinary scientific debate and the development of a new theory on the evolution of terrestrial life. Many people are still wondering today of how such a discovery came about: was is casual or was it the result of a methodic, scientific search? It would be fair to say that it was both. This fascinating story is told in detail by Alvarez (1997), and nobody better than the discoverer could have done it. Here is just a short account of one aspect of this discovery, which we think relevant and perhaps useful
198
for anyone who, one day, will find her or himself wondering while looking at the original K/T boundary outcrop in the Bottaccione Gorge. The distinct difference in fossil microfauna between the limestone layers above and below the K/T clay (see Fig. 5.7.2.1) was something more than a puzzling curiosity for the various interdisciplinary specialists, who worked together in the Gubbio team. The paleontologic answer to such a sharp change was that the thin clay layer was a hiatus, i.e., a long period of time represented by little or no sediment. How long was this unrepresented geologic time nobody could tell with confidence and precision, and that was the problem for the magnetostratigraphers in the team, who wanted to use the sequence of magnetic polarity reversals as a precise tool for calibrating the time scale. They needed to know how complete their Gubbio sequence really was. It is so that Ir was suggested, by nuclear physicist Luis Alvarez, father of geologist Walter of the Gubbio team, as a tracer for estimating the sedimentation rate of these pelagic limestones. This was based on the assumption that Ir, along with other platinum group elements, which are very scarce in the Earth's crust, but much more abundant in undifferentiated meteoritic matter (see Sect. 1.8), is accreted onto the planet' s surface at a more or less steady rate in the form of the socalled perennial fallout (i.e., micrometeorites). Pelagic carbonate sediments are made essentially of biogenic calcite constituting the hard parts of phyto- and zooplankton. These organisms are produced in the water column, and deposited on the sea floor at variable rates through time. The biogenic carbonate ooze may contain a variable component of windblown siliciclastic dust (i.e., mostly clay and some silt). The Scaglia Rossa limestones may contain from 3% up to 15% of this siliciclastic component. In the case of a prolonged suppression of carbonate production, or as a consequence of carbonate dissolution, only windblown clay is deposited and preserved on the sea floor. The basic idea of Luis Alvarez was to measure the concentration of the iridium tracer in the boundary clay and in the limestones below and above it through a known span of time, and by normalization, simply estimate the time represented by the K/T boundary clay. Following this reasoning, a higher than limestone background concentration of Ir was expected in the K/T clay, and that would have been proportional to the length of the alleged hiatus. While Ir turned out to be too scarce in the limestones to be used as a practical tracer for estimating the sedimentation rate, the boundary clay contained too much of it to be explained by a hiatus: the integrated amount of Ir in the boundary clay and in the basal 20 cm of the eugubina limestone above it would have represented a much longer time than the overall time span analyzed. This apparent paradox was explained by Alvarez et al. (1980) with the hypothesis of a catastrophic, massive accretion of an if-rich extraterrestrial object, such as a chondritic asteroid or perhaps the rocky part of a comet with an estimated diameter of 10 + 4 km. The impact explosion and its ejecta would have caused a sudden deterioration of the world's climate mainly by temporary obscuration of sunlight, with imaginable disastrous effects on the global biota and whole terrestrial and marine ecosystems (see Sect. 3.2.3).
199
Fig. 5.7.2.1. Polished slab of the 25 mm thick K/T boundary clay layer from Petriccio sandwiched between the top, white limestone of the Cretaceous, and the basal, pink limestone of the Tertiary (the eugubina limestone). Thin section photomicrographs (same magnification) show the planktonic foraminiferal assemblages in the limestones below and above the boundary. The largest foram test in the lower part of the picture is about 0.6 mm across.
200
It is not in the intention of this book to review all the work done by innumerable researchers, especially paleontologists and biostratigraphers, on the K/T boundary in the two decades following the Alvarez et al. (1980) paper. To those who are interested, we suggest to consult the Special Papers of the Geological Society of America edited by Silver and Schultz (1982), Sharpton and Ward (1990), Ryder et al. (1996), and the book by Hallam and Wignall (1997), all with exhaustive reference lists. A discussion of the evidence for impact at the K/T boundary is given in Sect. 3.2. As for the K/T boundary in our U-M Apennines, it must be recognized that no high-resolution biostratigraphic or micropaleontologic work has been carried out in the years immediately following the publication of the Alvarez hypothesis. One of the reasons for this neglect toward the classic Italian K/T boundary is that it may have seemed, in the eye of the stratigrapher, not so suitable for highresolution stratigraphical studies. The limestones bracketing the K/T clay are thoroughly homogenized by bioturbation, strongly cemented, and were deposited at rather slow rates, varying from section to sections from about 6-10 mm/ka for the top Cretaceous limestone, representing the Abatomphalus mayaroensis Zone, to 2-5 mm/ka for the basal limestone of the Tertiary, representing the Parvularuglobigerina eugubina Zone (the former Globigerina eugubina of Luterbacher and Premoli Silva 1964). In other K/T boundary sections around the world, where sedimentation rates are orders of magnitude higher than at Gubbio, and/or bioturbation less effective in homogenizing the soft marine sediment, a thin foraminiferal biozone is found between the A. mayaroensis Zone, and the P. eugubina Zone. This biozone is called P0 Zone and was first recognized by Smit (1982) based on the abundance of one single, dwarf foraminifer, the Gumbelitria cretacea, in a very short stratigraphic interval immediately above the sharp extinction level of the Cretaceous fauna. This creature was believed by Smit (1982) to be the sole planktonic foraminifer that survived the K/T boundary catastrophe. In short, the thin P0 Zone is not recognizable in the Italian K/T boundary sections. Possibly, the tiny tests of G. cretacea, which were deposited on the seafloor of the U-M basin immediately after the impact, were dissolved at a time of low pH at the water-sediment interface during the deposition of the boundary clay (see below). Perhaps, the upper part of the P0 Zone was formed when carbonate deposition and preservation was restored, but a thin lamina of G. cremcea tests would have been homogenized by bioturbation with the carbonate ooze of the overlying P. eugubina Zone. This would have rendered the thin P0 Zone unrecognizable. Moreover, the hardness of the eugubina limestone in the Italian sections is such that foraminiferal tests cannot be extracted and isolated, and species have to be recognized in thin section, which is a difficult, if not an impossible task, considering that these forams have dimensions around 40-50 ~m. The impossibility of recognizing a millimetric P0 Zone in the Gubbio and other Italian K/T sections may have discouraged high-resolution biostratigraphers in undertaking a detailed study in this unfavorable situation, and may have led some of them to believe that the K/T boundary in this area is a hiatus. As we will show
201
in the following chapters, there is no real hiatus in most of the K/l" sections in the U - M basin, and the absence of a P0 Zone cannot be considered p e r s e the evidence of unrecorded sedimentation in the time immediately following the K/T impact. In summary, following the aim of this book, we are now proceeding with a description of the high-resolution impact stratigraphy of the K/T boundary in the U M Apennines, documenting the evidences of the impact that can be readily recognized in the field and with simple laboratory tools. Then, we will describe the most representative outcrops in the region, where the K/T boundary can be easily reached and observed.
5.7.3 Sedimentary Setting and K/T Boundary "facies" Throughout the U - M basin, the K/T boundary is exposed in numerous accessible sections, and most of them have been studied to some extent. Even though the K/T boundary is always found in a genuine pelagic environment, it exhibits different lithologic characteristics from sections to section. Lateral variations in sedimentary facies of the Scaglia Rossa Formation reflect an irregular topography of the paleo-sea floor in an active synsedimentary tectonic setting (e.g., Chan et al. 1985; Alvarez et al. 1985; Montanari et al. 1989; see also Fig. 4.1.2). In the areas west of the Cagli and Camerino (i.e., Gubbio, see Fig. 4.1.1), the Scaglia Rossa is free of turbidites, although small scale soft sediment slumping is found locally (see, for instance, the K/T boundary section at Rocca Leonella, near Piobbico, described by Alvarez et al. 1985). On the other hand, the areas around Furlo and Monte San Vicino, in the central part of the U - M anticlinorium, were occupied by intrabasinal depocenters which were collecting frequent earthquaketriggered slump masses, and turbidites essentially made of reworked planktonic foraminiferal tests. Finally, in the areas near the margins of the Abmzzo and Adriatic carbonate platforms (i.e., Monti Sibillini, Montagna dei Fiori, and Monte Cbnero), the Campanian to lower Eocene Scaglia Rossa pelagites are interbedded with thick and coarse calcarenitic turbidites continuing shallow water bioclasts. On the basis of the color of the K/T boundary clay and the enclosing limestones, and differences in the type and relative abundances of authigenic and pseudomorphic minerals within altered impact spherules, Montanari (1991) recognized at least four different U - M K/T boundary "facies" (Fig. 5.7.3.1). Apart from the authigenic mineralogy of the altered impact spherules, which is described below, rock colors are sufficient for recognizing these different "facies" in the field.
=. O ==
c~
e~
~.~
~ p y r i t e
MONTAGNA DEI FIORI
SPHEROIDS RELATIVE ABUNDANCE
15 mm green
3 mmgreen
gray-green to gray
pale green toochre
pale green
pale green
bright green
GLAUCONY COLOR
Jllll|lWu|mullllllhematite ~ g o e t h i t e
~.'-:~':~,,':~!~,::'~i~
•~i ..*.i~:~:~!~:~:i~:/i~;:;!~!~!~!~!~i~i~16 i~i rnm ochre ::::::::::::::::::::::::::::::::::::::::::::::::
5 mm green
21 mm red
4 mm green
lOmre°
K/T CLAY THICKNESS AND COLOR
~i~pii~i:::~.~ ::i~!:g:i~gi~~.; i!i~!~ii~,>i!:.!;i~i!i~ii~il/! .i:i:i::;:.,'.~:~:~:;:~:.~::~!:!$!~]~:~!:)!:~:i~:!
lllINll
FORNACI QUARRYC. (Monte Cbnero) I
RETRALATA (Furlo)
PETRICCIO (Acqualagna)
CONTESSA (Gubbio)
OUTCROP
whitish
beige
dark pink
dark pink
dark pink
TERTIARY LIMESTONE COLOR
Iii~,~::~;~:~%::~!4glaucony I
white
white
light pink
white
white
CRETACEOUS LIMESTONE COLOR
tK-feldspar
8.30 ± 0.50
10.29 ± 0.48
2.14 .+.0.18
8.30 ± 0.51
2.94 + 0.16
Ir (ppb)
BULKK/T CLAY
203
At Gubbio (i.e., Bottaccione, and Contessa sections), as in every other outcrop of Scaglia Rossa in the U - M Apennines exhibiting a typical turbidite-free facies (see the descriptions of these outcrops and those of the Petriccio and Frontale below), the uppermost layer of the Cretaceous is white, which contrasts with the characteristic pink color of underlying Cretaceous limestones, and the slightly darker pink limestones of the basal Paleocene. The K/T boundary clay layer of the Gubbio "facies" is dark red, with a thin gray-green sole at the base (Fig. 5.7.2.1). The white color of the top Cretaceous limestone has been attributed to iron reduction and leaching, and consequent bleaching of the oxidized, pink pelagic ooze, following a brief episode of anoxia at the water-sediment interface (Lowrie et al. 1990; Montanari 1991). This low-Eh condition was probably caused by anoxic bottom waters, rich in organic matter, which formed on the abyssal sea floor immediately after the mass killing of the marine plankton. In the Furlo turbiditic basin, the K/T boundary "facies" is characterized by a thin, entirely red clay layer (no green sole is present here), and a light pink color of the top Cretaceous, unbleached limestone. The Monte C6nero K/T boundary "facies", which is well exposed in several outcrops in the C6nero promontory south of Ancona, is characterized by a light ochre color of the boundary clay, which exhibits a thin greenish-gray sole. The Cretaceous pelagic limestones, which are interbedded with thick and coarse calcarenitic turbidites, are here whitish all the way up to the boundary, whereas the basal Paleocene limestones (i.e., the P. eugubina Zone) are of a light yellowishbeige color. Therefore, in this area the bleached top Cretaceous limestone is not recognized. Finally, in the Montagna dei Fiori section, where the sedimentary facies of the uppermost Cretaceous and lowermost Tertiary Scaglia Rossa is similar to the one of Monte C6nero (i.e., thick and coarse calcarenitic, white turbidites interbedded with whitish pelagic limestones), the K/T boundary clay is entirely green. This is the only locality known in the U - M basin where pyrite is found in the K/T boundary clay, and neither K-feldspar nor goethite or hematite are present (Fig. 5.7.3.1).
5.7.4 Impact and Catastrophe Signatures in the U-M K/T Clay In this section, we review briefly the impactoclastic evidence that can be found in the K/T boundary clay in the U - M basin. Besides iridium (and other trace elements that are related to the impact fallout but can be detected only with sophisticated laboratory analysis), microspherules and shocked quartz grains can be easily picked and observed after simple washing and concentration procedures, and with standard optical microscopes (see Sect. 6.2.2). In addition to this mineralogic evidence, we found it helpful to discuss also the benthic foraminifers and bioturbation, which constitute clear biologic signatures of the impact-triggered crisis in this deep marine environment. An explanation of the high-resolution event stratigraphy across the Italian K/T boundary will be proposed in Sect. 5.7.5 and it is based mainly on the geochemical, mineralogical, and paleontological indicators of
204
the unusual and short-lived local paleoenvironmental conditions related to the global catastrophe. More detailed and specific information for representative K/T boundary outcrops in the U - M region will be given in Sect. 5.7.6. I r i d i u m . In addition to I N A A by Alvarez et al. (1980), which was carded out on samples from the U - M sections of Bottaccione, Contessa, Acqualagna, Petriccio, and Gorgo a Cerbara, the bulk K/T boundary clays from thirteen other U - M sections were also analyzed with the coincidence spectrometer by Frank Asaro at the Lawrence Berkeley Laboratory, as reported in Montanari (1991; see Table 5.7.4.1). No significant Ir concentrations were detected in the U - M sections at Genga and Fossombrone. In both cases, the analyzed clay samples were not from the "standard" K/T boundary, but, rather, from clay-rich levels marking stratigraphic hiati between limestones with Cretaceous foraminifers below, and Paleocene foraminifers above. No spherules or shocked quartz grains were found in these clay-rich layers. These hiati resulted from the removal, probably by bottom current winnowing and/or slumping, of unconsolidated pelagic sediment. Several basal Paleocene biozones are, in fact, missing in these sections (Luterbacher and Premoli Silva 1964; Montanari 1991). In every other K/T section analyzed in the region, anomalous concentrations of iridium were found in the boundary clay. However, the elemental concentrations vary significantly from section to section, from a minimum of 1.19 _+ 0.16 ppb in the Furlo Via Flaminia section, to a maximum of 10.29 _+ 0.48 ppb in the Fornaci Quarry C. section. This variability is probably due to local preservation factors, such as bioturbation, alteration and/or tectonization of the outcrop, which may have caused remobilization and loss of Ir. An exception may be the two sections analyzed at Furlo (Pietralata and Via Flaminia), where in both cases the concentration of iridium is relatively low (Montanari 1991). In this area of the paleobasin, winnowing by bottom currents effectively remobilized the fine fraction of the pelagic sediment (Montanari et al. 1989), and may have remobilized also some of the Ir-rich impact fallout component during, or soon after, its deposition. Fig. 5.7.4.1. a) Altered microkrystites from the Italian K/T boundary clay: the black spherules are made of goethite (Go), the green ones of glaucony (G1), and the white ones of K-feldspar (Kf). Notes some dumbbell-shaped K-feldspar spherules (db). b) thin section microphotograph (plain light) of a K-feldspar spherule from the Petriccio section. Note the dendritic (D) and fibrous (F) structures reminiscent of quenched clinopyroxene and calcic feldspar crystals, c) SEM image of an altered impact spherule made of glaucony (Petriccio section) showing dissolution pits identical to those found on Late Eocene microtektites (for comparison see Fig. 2a8 in Sanfilippo et al. 1985), and on impact glass spherules from Mexican K/T boundary sections (see Smit et al. 1992). d) SEM image of a polished glaucony spheroid from the Fornaci central quarry section of Monte Crnero, exhibiting clear dendritic structures identical to those found in Late Eocene clinopyroxene microkrystites (compare with Fig. 5g in Glass et al. 1985). e) extra thin section (1 ~tm thick) microphotograph (transmitted, plain light) of goethite impact spherules from the Petriccio section, showing various arrangements of spinel microcrystals (black spots), and internal fibrous structures reminiscent of a quenched silicate melt. f) back-scattered SEM image of a magnesioferrite spinel from a goethite spheroid from the K/T boundary clay of Petriccio exhibiting skeletal structure. --+
L~
206
Detailed Ir measurements across the K/T boundary interval, and through the actual K/T boundary clay layer, were carried out at Bottaccione and Petriccio, respectively, as will be discussed in Sect. 5.7.6. Impact microspherules. Microspherules made of K-feldspar, with a diameter of 0.1-0.8 ram, were first discovered in the K/T boundary clay of the Spanish Caravaca section by Smit and Klaver (1981). Although an impact origin for the spherules was inferred by these authors, their mineralogy similar to (volcanic) high-sanidine remained somewhat more difficult to explain, until 8180 analyses by DePaolo et al. (1983) showed the sanidine to be low-temperature K-feldspar replacement. Soon after this discovery, cooperative work with Jan Smit led to the identification of similar spherules also in the Italian K/T boundary, as well as in the Central Pacific DSDP Site 465A (Montanari et al. 1983).
Table 5.7.4.1. Major components of the sand-size fraction, and bulk-rock iridium content in the K/T boundary clay layer of the northeastern Apennines outcrop
sparry
Cretac,
Tertiary
Miocene
calcar,
calcite
plankton
plankton
contamin,
benthos benthos
arenac,
spheroids
tr (ppb)*
1 Bottaccione
A
A
A
A
A
A
P
6.06 ± 0.13
2 Contessa
A
S
S
S
S
A
P
2.94 -+ 0.16 3.13 ± 0.35
3 Pontedazzo
A
N
N
X
S
A
P
4 G o r g o a Cerbara
A
N
N
X
S
A
P
8,74 ± 0.57
5 Maest~t Confibio
A
N
N
X
S
S
P
6.01 -+ 0,71
6 Casacce
A
N
N
X
N
S
P
5.30 ± 0,40
7 Colcanino
S
N
N
X
S
A
P
6.28 -+ 0,48
8 Acqualagna
A
N
N
X
S
A
P
5.10 ± 0.30
9 Petriccio
N
N
N
X
S
A
P
8.30 ± 0.51"*
10 Furlo V. Flaminia
A
S
S
X
S
A
P
1.19 +- 0.16
11 Furlo Pietralata
S
S
S
X
S
A
P
2.14 -+ 0A8
12 Fossombrone
A
A
A
A
X
A
X
< 0.38
13 Genga
A
A
A
X
S
S
X
< 0.23
14 Frontale
N
A
A
X
S
A
P
4.51 +- 0.58
15 Cingoli
S
A
A
X
S
A
P
7.11 ± 0.44
16 Ceselli
A
N
N
X
S
A
P
2.69 ± 0.32
17 M.gna dei Fiori
A
N
N
X
X
N
P
8.30 ± 0.50
18 Fornaci Quarry c.
S
S
s
x
s
A
P
10.29 ± 0.48
* **
Ir data are from M o n t a n a r i (1991). Iridium c°ntained in the central part ° f the layer'
A = abundant; S = scarce; N = v e r y scarce or n e g l e c t a b l e ; X = absent: P = present.
Note: relative abundances were estimated visually w i t h a b i n o c u l a r m i c r o s c o p e o n > 6 4 ~ m washed residues.
The Italian K/T clay is made of various clay minerals, including illite, smectite, kaolinite, and mixed layered illite-smectite clay. This composition is essentially
207
identical to the detrital clay component in the pelagic limestones below and above the boundary (e.g., Johnsson and Reynolds 1986; Montanari 1991). In addition, the K/T boundary clay contains variable amounts of secondary calcite crystals, which were precipitated within the clay during tectonic bedding-plane parallel flexural-slip folding. The insoluble residue >63 gm constitutes 0.01 wt.% of the bulk rock, and is made up of altered impact microspherules, arenaceous benthic foraminiferal tests, and very rare detrital quartz and (even rarer) feldspar grains. Up to two hundred impact microsphernles per cubic centimeter of bulk rock can be found in the Italian K/T boundary clay (Montanari et al. 1983). These are made of different authigenic minerals reflecting a complex process of diagenetic alteration. Moreover, ratios between these minerals differ from section to section, indicating lateral variations of redox conditions in the early diagenesis of the K/T boundary clay throughout the basin. In addition to whitish spherules made of a Kfeldspar, structurally similar to high-sanidine, and, thus, almost identical to the Kfeldspar of the Spanish sphernles of Smit and Klaver (1981), the Italian K/T clay contains also spherules of bright green to gray glaucony, and black, strongly magnetic goethite (Fig. 5.7.4.1a). These spherules, especially the glauconitic ones, are flattened to various degrees, with axial ratios as large as 10:1, and for this they were originally called "spheroids" by Montanari and co-workers. The K-feldspar spherules are often pitted on the surface and sometimes they exhibit dumbbell shapes (Fig. 5.7.4.1a). Internally, as seen in petrographic thin sections, they are characterized by fibro-radial or fan-shaped arrangements of Kfeldspar crystals. More rarely, ghosts of skeletal or dendritic crystals are present (Fig. 5.7.4.1b). These crystal shapes, along with the composition of the Kfeldspar, which is a common low temperature alteration product of oceanic pillow basalts, lead Montanari et al. (1983) to the inference that the K/T spherules were originally made of a quenched basaltic melt, similar to impact clinopyroxene spherules described by Glass et al. (1985) in upper Eocene marine sediments, and, thus, they represented altered microkrystites (see also DePaolo et al. 1983, and Smit etal. 1992). The Italian K-feldspar spherules contain 1.02+ 0.11 ppb Ir (Montanari et al. 1983), indicating that they were contaminated by the impactor. Glauconitic spherules are present in all the K/T boundary clay samples analyzed by Montanari (1991) in the U-M basin. Their color, from bright green to gray, and maturity as indicated by their relative I(20 content (Odin and Fullagar 1988), vary from section to section, reflecting variable redox conditions throughout the paleobasin's sea floor. In thin section, these flattened spherules exhibit the typical pinpoint texture of the glaucony, and no particular structure reminiscent of their precursor mineralogy is usually visible. However, in a few rare cases, claucony sphernles exhibit a peculiar pitted surface very similar to that of Late Eocene Caribbean microtektites (Sanfilippo et al. 1985), and of K/T impact glass sphernles from Mexican sections (Smit et al. 1992) (Fig. 5.7.4.1c). Only in some cases elaborate dendritic internal structures in glaucony spherules are emphasized by back-scattering SEM imaging of polished surfaces (Fig. 5.7.4.1d), suggesting that, in such cases, quenched clinopyroxene was the precursor mineral prior to diagenetic alteration. This, in fact, is the common
208
mineralogy of Late Eocene micro-krystites described by Glass et al. (1985), which show internal dendritic structures virtually identical to those of the altered K/T spherules, as well as of some unaltered microkristites found by Smit et al. (1988) in the K/T boundary of an Atlantic deep sea core.
Fig. 5.7.4.2. Thin section microphotograph(crossed polars) of a shocked quartz grain, about 0.1 mm across, from the K/T boundary clay of Petriccio, exhibiting two clear sets of PDFs.
Black magnetic spherules in the Italian K/T boundary clay were fist described by Montanari et al. (1983) who, on the basis of early XRD and INAA data, misinterpreted their mineralogy: they thought they were made of magnetite crystallites suspended in an impure microcrystalline quartz matrix. Instead, specific geochemical and mineralogic studies (Smit and Kyte 1984; Kyte and Smit 1986; Montanari 1991) showed that these spherules are made of tiny crystallites of magnesioferrite-magnetite spinel suspended in a translucent, rust color goethite matrix. Flow-textural and fibrous structures, as seen in extra thin sections (-1 gm thick), characterize the goethite matrix, whereas the spinel crystallites are often aligned along these matrix structures (Fig. 5.7.4.1d). In other cases, spinel crystallites are sparse and randomly distributed throughout the spherules, or distributed in concentric rings. SEM imaging of the spinel reveals dendritic and skeletal habits indicating quenched crystallization (Fig. 5.7.4.1e). Further detailed mineralogic and geochemical analyses led Robin et al. (1992) and Gayraud et al. (1996) to propose
209
that these K/T spinels were formed by ablation in the lower atmosphere of large projectile debris possibly generated in a low angle asteroid impact (see Sect. 3.2.1.8). Spinel-bearing goethite spherules are absent in the relatively reduced K/T boundary clays of the Monte Cbnero and Montagna dei Fiori sections. In the former, only more or less ferroan glaucony and K-feldspar spherules are present, whereas in the latter section, glaucony is associated with euhedral pyrite. In addition to these dominant types of altered spherules, the Italian K/T clay contains rare spherules with mixed mineralogies (Montanari 1991). Most commonly, glaucony is associated in the same spherule with K-feldspar or with goethite, but rarely, if at all, the three mineralogies are present together in the same spherule. Shocked Quartz. Shocked quartz grains (see Sect. 1.6) in the U - M K/T boundary clay were first reported by Bohor and Izett (1986), confirming the worldwide distribution of this unmistakable indicator of impact shock metamorphism originally discovered by Bohor et al. (1984) in North American K/T boundary sections (see Sect. 3.2.1.5). In the Italian K/T boundary, these grains are angular and rarely larger than 0.1 mm (Fig. 5.7.4.2). In the Petriccio outcrop (see Sect. 5.7.6), quartz grains are concentrated in the basal 5 mm thick green sole of the boundary clay. Out of -230 quartz grains per 100 g of bulk rock, 20 grains show single and multiple sets of PDFs (Montanari 1991). In contrast, the red part of the boundary clay contains no more than 50 grains of quartz per 100 g of bulk rock, and about 10-15% of them show lamellar features. The concentration of quartz grains at the base of the boundary clay was confirmed by one of us (A.M. unpublished data) in a test in the Monte Cbnero section of Fonte d'Olio (see Sect. 5.7.6). Benthonic Foraminifera. In addition to spherules, variable amounts of secondary calcite crystals, very rare quartz grains (and even fewer feldspar and other non-carbonate minerals), and rare fish teeth, the >63 ~tm washed residue of the Italian K/T boundary clay, contains a well diversified benthic foraminiferal assemblage dominated by arenaceous tests of agglutinating Textulariina species. Calcareous tests of Osangularidae and Gavellinellidae are rare and often show clear signs of dissolution, whereas Cretaceous and/or Tertiary planktonic foraminiferal tests are usually absent or very rare, except in a few sections, where they were probably introduced into the clay layer by later bioturbation (Montanari 1991; see also the description of the Frontale outcrop in Sect. 5.7.6). Textulariina are very rare in the limestones of the Scaglia Rossa formation. Although many species of this Suborder are well adapted to deep water environments, they favor siliciclastic sediments, which provide silt and fine sand grains of hard silicates, such as quartz and feldspar, that they selectively collect and agglutinate to make up their resistant tests. Arenaceous foraminifers are found also in clay layers above and below the K/T boundary, and throughout the whole U - M carbonate sequence, but the rich and diversified assemblage in the K/T boundary clay, which is represented by some 16 genera and 35 species for a total of up to 40 specimens per gram of bulk rock (Fig. 5.7.4.3), led Coccioni and Savelli (1983) to
210
conclude that the K/T boundary clay represents a sudden change from normal to unusual lower bathyal paleoenvironmental conditions. A recent detailed study of the benthic foraminiferal assemblage in several sections of the U - M basin by Coccioni and Galeotti (1998) confirmed these early observations. They concluded that during the sedimentation of the K/T boundary clay in the lower bathyal sea floor of this basin (i.e., 1500-1800 m below sea level), benthic foraminiferal communities show an increase in species richness, and a "bloom" of low-oxygen tolerant, infaunal, detritus-feeding species (e.g., Spiroplectammina ss.pp.), which indicate an increase in organic flux to the sea floor, and a concurrent decrease in oxygenation at the water-sediment interface. Slight variations in reciprocal proportions among Textulariina genera and species from section to section throughout the basin indicate lateral variations of redox conditions, probably controlled by topography, bathymetry, and bottom current activity. In the relatively reduced, more proximal and perhaps shallower Monte Ctnero area, for instance, Spiroplectammina tests (the most common genus in the Italian K/T boundary clay) are more abundant and larger than those found in deeper and better oxygenated central areas of the paleobasin (i.e., Petriccio, Furlo, Gubbio). In the pyrite-bearing, green K/T boundary clay at the Montagna dei Fiori section, benthic foraminifers are practically absent, except for a very few tests of
Ammodiscus. In summary, although in more proximal and shallower settings throughout the K/T world's oceans the benthic foraminiferal community testify to drastically stressed sea floor environments, and even mass extinction (see Coccioni and Galeotti 1998, and references therein), in the lower bathyal U - M basin arenaceous Textulariina were less affected by the catastrophic event in terms of extinction, and actually they were somewhat favored by the sudden low oxygen and high organic nutrients conditions produced by the planktonic mass killing. Bioturbation. One of the most peculiar macroscopic aspects of the K/T boundary interval in the U - M basin is the high concentration of trace fossils within the top white layer of the Cretaceous. This anomalous occurrence can be better appreciated if compared with the normal sedimentological setting of the Scaglia Rossa limestones. In fact, these limestones are usually homogenized by bioturbation activity occurring during a slow (3 to 10 mm/ka) pelagic carbonate sedimentation on a well-oxygenated sea floor. Changes in sedimentation rate and/or brief interruptions of the carbonate production are probably controlled by cyclic climatic changes affecting the primary productivity of the surface sea water. The result is an obvious rhythmic layering of the Scaglia Rossa, emphasized by pressuresolution pseudobedding (stylolitization) produced by sediment loading (Alvarez et al. 1985).
211
Fig. 5.7.4.3. Some common Textulariina arenaceous benthic Foraminifera from the K/T boundary of Frontale. S = Spiroplectammina ; D = Dorothia; R = Rhyzammina; B = Bathysiphon; T = Tritaxia; V = Verneulina; Re = Reophax; So = Sorosphaera.
The abundant bottom dweller's activity on the very top sediment of the Scaglia Rossa sea floor is excellently documented at the interface between calcarenitic turbidites and the underlying pelagic limestones (i.e., Furlo and Monte San Vicino areas). Here, the sudden arrival of fine grained turbidites essentially made of reworked planktonic foraminifers, have stopped the ongoing bioturbation activity, and a well diversified ichnofauna is preserved (Fig. 5.7.4.4.). This is mainly represented by traces of P l a n o l i t e s and large, flattened Z o o p h y c o s , and more rare H e l m i n t o i d e a , P a l e o d y c h t i o n , Scolicia, and S u b p h y l l o c h o r d a (Montanari 1979). In the normal sedimentological setting of this formation, some well-preserved traces of Z o o p h y c o s can be seen in cross-section below prominent clay layers (Figs. 5.7.4.5a, b). In summary, continuous reworking of the top sea floor sediment is carried out by bottom dwelling organisms. However, sudden interruption of planktonic productivity allows the sedimentation of only windblown clay and silt, and a concurrent cessation of bioturbation activity with the consequent preservation of a thin, unhomogenized clay-rich layer. As soon as normal nutrient-rich, but slow carbonate sedimentation is restored, bottom dwellers activity restarts, and the new surface sediment gets bioturbated while it accumulates. During this process, however,
212
some organisms, while feeding at the surface, burrow deeper than others in the subbottom leaving patterned traces of Zoophycos (Fig. 5.7.4.5). A recent study by Le Rousseau et al. (1996) showed that, in the basal 10 m of the Tertiary at Gubbio, Zoophycos "acmes" have a rhythmic occurrence, possibly reflecting Earth's orbit eccentricity cycles (i.e., -100 ka).
Fig. 5.7.4.4. Bottom surface of a calcarenitic turbidite of the Scaglia Rossa (Furlo Upper Road section), showing a complex network of Planolitestrace fossils.
The ichnofossit record at the K/T boundary can be considered a magnification of the normal process of bioturbation versus sedimentation desc~bed above. The difference is that the interruption of planktonic carbonate production represented by the K/T boundary clay was more drastic and lasted a much longer time than any of the cyclic clay episodes recorded above and below the boundary.
213
Fig. 5.7.4.5. Fossil traces of Zoophycos in the pink pelagic limestone of the Scaglia Rossa at Furlo. a) plane view (from the top surface of layer; b) vertical section on a polished slab of a limestone layer.
Zoophycos traces are the most conspicuous and are immediately visible on the outcrop. They are distributed along the white top limestone layer of the Cretaceous, and may reach 30-40 cm in diameter, 15-20 cm in height, and as many as two or three traces can be counted in a meter of exposed section along strike. The apex of these traces rarely reach the base of the overlying K/T clay layer. These ichnofossils are associated with randomly distributed Planolites traces. The number, size, and density of fossil traces vary from section to section. In the Petriccio section, for instance, as well as at Gubbio, Zoophycos in the range of 20 cm in diameter seem to be the predominant ichnofossils. In the Furlo area, where the light pink uppermost Cretaceous limestone is not completely bleached to a white color, and the K/T boundary clay is entirely red, bioturbation appears much more intense and diversified than in any other outcrop in the region. In the whitish K/T boundary transition of Monte C6nero, trace fossils are rare and small compared to Gubbio and Furlo, whereas in the pyrite-bearing Montagna dei Fiori section trace fossils are absent.
214
Fig. 5.7.4.6. a) Thin section microphotograph (plain light) of a Planolites burrow in the top Cretaceous limestone from the Pietralata section filled with tiny planktonic foraminiferal tests derived from the overlying Tertiary eugubina limestone; b) photograph of a polished slab of the top Cretaceous limestone from the Pietralata section showing the typical chevron structure of a Zoopycos burrow. Note a goethite (Go) and three glaucony (G1) spherules contained in the burrow; c) reddish Planolite burrow penetrating the white top Cretaceous limestone immediately below the base of the K/T boundary clay at Petriccio. Small divisions in the scale at the top of the picture are millimeters; d) Planolites burrow filled with white top Cretaceous sediment in the red basal Tertiary limestone from the Torricella section (Furlo anticline). Tiny dark specks dispersed in the homogenized red biomicrite are altered microkrystites derived from the underlying K/T boundary clay. Same scale as in Fig. 5.7.4.6c.
215
Planolites and Zoophycos burrows penetrating the top Cretaceous sediment are filled with the tiny Tertiary foraminifers that make up the overlying eugubina limestone (Fig. 5.7.4.6a). Altered microkrystites of K-feldspar, glaucony, and goethite are often found in these burrows (Fig. 5.7.4.6b), along with fragments of green and red boundary clay. The color of these traces is usually dark or red, strongly contrasting with the bleached white color of the enclosing terminal Cretaceous limestone (Fig. 5.7.4.6c). Conversely, "return" burrows penetrating the dark pink or red eugubina limestone from below, are white, and filled with uppermost Cretaceous biomicrite (Fig. 5.7.4.6d). These color contrasts and the spatially confined location of these burrows clearly indicate that, after a brief pause of bioturbation, bottom dwellers restored their burrowing activity at the very base of the eugubina layer, penetrating downward across the K/T boundary layer into the still unconsolidated top Cretaceous sediment. While this renewed biologic activity was in progress, the top Cretaceous sediment was already reduced and bleached, the low-Eh authigenesis of glaucony was accomplished, and the environment at the water-sediment interface was oxidizing. 5,7.5 High-resolution Impact Stratigraphy of the K/T Event Despite an elusive P0 Zone, which is unanimously accepted as the first biozone (i.e., the first biostratigraphic record) of the Tertiary, it cannot be said that the K/T boundary in the U-M basin is incomplete or that it bears a long hiatus. On the contrary, the combined geochemical, sedimentological, mineralogical, and paleontological data gathered in this deep water, pelagic basin, are sufficient for reconstructing with confidence and good resolution the sequence of exceptional events following the terminal Cretaceous catastrophe. It is just a matter of scale: in the U-M sections the appropriate tool for sampling and studying the stratigraphy of the K/T boundary are tweezers, instead of the classical hammer that is used in more expanded sections throughout the world. On the basis of what we have documented in the preceding chapter, we describe now the various interpretative steps of environmental changes across the K/T event, starting in the uppermost Cretaceous, and ending in the lowermost Tertiary. The Days Before. The general environmental crisis that characterized the lower-mid Maastrichtian with an extended period of low productivity, water cooling, extinctions, and biologic turnovers (and also impacts; see Chap. 5.7.1) was over, and the situation in our U-M deep-water basin at the very end of the Cretaceous was, oceanographically speaking, florid. Variations in productivity and diversity of the planktonic foraminiferal population was mainly controlled by Milankovich cyclicity, which imparted to the Scaglia Rossa its typical rhythmic bedding. Chauris and Le Rousseau (1996) carried out a detailed (-5 cm intervals) cyclostratigraphic analysis of the top 110 cm of the Cretaceous in the classic Contessa highway section, using carbonate abundance and relative counting in thin section of important foraminiferal genera and species. They came up with the
216
identification of two peaks in carbonate abundance coinciding with relative abundance peaks of selected foraminiferal taxa, which they interpreted, on the basis of the duration and mean sedimentation rate for the C29r interval (-6-6.2 m/m.y.), as reflections of the -100 ka orbital excentricity cycle (Fig. 5.7.5.1). The last peak in relative abundance of six foraminiferal taxa (Rosita contusa, Globotruncanita sp., Racemiguemelina fructicosa, Rugoglobigerina sp., Globotruncana sp., and Hedbergella sp.), which coincides with a peak in CaCO 3, is located about 45 cm below the K/T boundary clay. The foraminifers in the uppermost sample of the Cretaceous seem to suggest the beginning of a new positive cycle, which was sharply interrupted by the K/T event.
number of tests per thin section
65.0 347.5
347.0
65.1 m
Ma
346.5 91
92
93
94
95
96
CaCq~ keeled globotruncanids M
rugoglobigerinids R. fructicosa
Fig. 5.7.5.1. Variations of index fossils abundance and whole rock calcium carbonate content in the last 1.1 m of the Cretaceous at Gubbio. The two main peaks are probably related to the excentficity of the Earth's orbit (from Chauris and LeRousseau 1996).
217
Renon (1997) extended for several meters down section, at Gubbio and elsewhere in the U-M basin (i.e., Furlo and Monte C6nero), the investigation of Chauris and Le Rousseau (1996), using detailed stratigraphic, calcimetric, and quantitative biostratigraphic analyses, and reached the same conclusions as his French colleagues. In summary, at the very end of the Cretaceous, the planktonic foraminiferal population in the U-M pelagic basin went over a minimum in productivity, reflecting environmental stress, as they did so many other times, cycle after cycle, in the preceding millions of years. Unfortunately, these marine organisms could not make a profit of a newly restored positive trend, as they were suddenly and radically exterminated by the bolide impact at the Yucatan Peninsula in Mexico. The Days After. It must have been a difficult awakening for the U-M plankton the day after the armageddonian impact on the Campeche platform in Yucatan. Gaseous and particulate matter produced by the expanding impact cloud may have completely blocked the sun light, and a deadly blanket of darkness and cold enveloped the whole planet in a matter of hours or days. The once fertile photic zone of the marine realm became quickly a field of death. It is difficult to say how long the agony of the world's oceans lasted. Darkness and cold may have gone on for months before the most opaque fraction of the impact cloud settled on the Earth's surface, but the marine plankton would have probably survived less than that. The phytoplankton, including the Coccolitophorida, which were at the very bottom of the oceanic food chain, and provided most of the calcium carbonate making up the Scaglia Rossa pelagic mud, was probably the first to have died out. The sudden darkness would have interrupted their vital photosynthesis inexorably. Soon after that (perhaps a matter of days to months) was the turn of the zooplankton, including the Foraminifera, which provided 10 to 30% of the calcium carbonate of the Scaglia Rossa limestone. Some species, such as those which were adapted to dwelling also below the photic zone, may have had the chance to see a feeble sunlight once more after the gloomy impact winter was over; but the atmosphere, now free of most of the opaque impactoclastic matter, still contained gases such as CO2, water vapor, and SO2 + SO 3 released from the instantaneous vaporization of the limestones and evaporites in the shallow sea of the Campeche platform, along with nitrous monoxide formed by the impact-generated superheating of the atmosphere. This formed a deadly atmospheric cocktail, which would be reprecipitated as torrential acid rains, causing long lasting greenhouse conditions at a global scale. All this had an immediate effect on the pelagic sedimentation, in the U-M basin as everywhere else around the world. Carbonate production was suddenly interrupted, and only windblown silt and clay reached the sea floor, along with the fine ejecta of the distant impact. In the months after the catastrophe, a huge amount of dead organic matter, plankton and nekton alike, with or without hard parts, slowly settled in the deep of the oceans. At first it could have seemed a manna for the benthic inhabitants of the abyss, but soon this excess of quickly decaying organic matter turned the already precarious environment of the bathyal sea floor into an anoxic, acidic place, where life could barely be supported.
218
Worms and other bottom dwellers, which in past times were meticulously gardening the well-oxygenated sea floor with an incessant bioturbation activity, came to a sudden rest. Only detritus feeding, low-oxygen tolerant benthic microorganisms managed to populate this silent, barren environment. After this, the K/T boundary clay started to accumulate on the Scaglia Rossa sea floor. A few millimeters of the very top Cretaceous carbonate ooze, as well as the lamina of dead calcareous plankton killed by the impact, were probably dissolved in the film of stagnating bottom water acidified by the decaying organic matter. This is suggested by the corroded top surface of the uppermost Cretaceous limestone, and the thin green clay lamina at the base of the K/T clay layer perfectly adhering on top of it. Reduction progressed downward in the water-saturated, well-oxidized terminal Cretaceous ooze causing dissolution and remobilization of now reduced iron particles, and bleaching of the once pink carbonate sediment (Lowrie et al. 1990). This process of dissolution and bleaching did not happen in the Furlo basin, where bottom currents freed the sea floor from the stagnating film of low-pH, low-Eh water. Here, the top limestone layer of the Cretaceous exhibits a light pink color, and it does not seem to have a corroded upper surface. Moreover, the overlying K/T clay lacks the green sole, and its Ir content is significantly lower than the average Italian K/T clay (Montanari 1991). In summary, while throughout most of the deep sea floor of the Scaglia Rossa basin the thin carbonate layer of the "day after" hecatomb was dissolved away by the acidic "nutrient soup" (Coccioni and Galeotti 1994), at Furlo it was swept away by local bottom winnowing (Montanari et al. 1989). How long did this situation last before almost normal conditions in the surface water restored carbonate sedimentation? The answer to this intriguing question is contained within the 0.8 to 2.6 mm thick boundary clay: way too thin a page of Earth history, anyone would say, to read what happened in the oceans during the millenia after the impact. But cautious tweezers may find, in fact, interesting hints leading to a satisfactory answer. The Millennia After. Accepting that Gumbelitria cretacea was, in the planktonic foraminiferal population, the only survivor of the K/T catastrophe (the P0 Zone), and that in more expanded sections such as the GSSP for the K/T boundary at E1 Kef, Tunisia, a high-resolution biostratigraphy can be drawn from the base of the P0 Zone up through the various subsequent phases of the repopulation of the planktonic realm (Smit et al. 1997; Canudo 1997; Masters 1997; Olsson 1997; Orue-etxebarria 1997; Keller 1997; Smit and Nederbragt 1997), the question arises: why isn't this lucky planktic foraminifer present in the Italian K/T clay? One reasonable answer to this question is that the tiny tests of this biserial globigerinid, along with the micrometric platelets of surviving Coccolitophorida, were dissolved in the low pH-low Eh post-impact environment of the Scaglia Rossa sea floor. It could well be that G. cretacica and coccoliths were forming their thin P0 Zone also after the K/T clay was deposited, when the low-pH conditions at the water-sediment interface were buffered by the arrival of conspicuous new biogenic carbonate, but at that point, restored bioturbation activity would
219
have mixed up the new Tertiary sediment, yielding what is today recognizable as a homogenized eugubina limestone. Thus, because G. cretacea cannot help answering any question, either because it was dissolved (so it is no longer there) or because it was vertically mixed by bioturbation and confused with its descendants, the question should be addressed to the inorganic world and their numbers: how long did the crisis last in this basin? A first estimate can be derived from the thickness of the K/T clay layer. The clay itself is practically identical to the clay making up the fine windblown, siliciclastic fraction of the enclosing Cretaceous and Tertiary limestones. At Gubbio, the Cretaceous part of Chron 29r is about 4.1 m thick and represents about 500 ka (using the time scale of Gradstein et al. 1995; see Fig. 5.7.1). Thus, the average sedimentation rate for this pre-K/T interval is 8.2 mm/ka. An average of 5% of the pre-K/T limestones is made of clay. From this, we can derive a sedimentation rate for the clay of about 0.04 mm/ka. In short, a 20 mm boundary clay would correlate roughly to 50 ka. One problem here is that the K/T clay thickness vary laterally due to local tectonic shearing and compaction. A thickness of 20 -+ 10 mm can be considered a realistic estimate representing the U - M K/T clay layer, and, thus, a time of 50 _+25 ka is the best estimate we can derive for its time duration. This estimate would become even smaller, roughly 30 + 15 ka, if we use the sedimentation rate of about 5.6 mm/ka for the lowermost Tertiary limestones in the Bottaccione section, derived from the time scale of Berggren et al. (1995). The imprecision of the time estimate for the duration of the K/T boundary clay episode in the U - M basin is mainly due to the inaccuracy of the actual stratigraphic record (completeness, compaction, and consistent rate of sedimentation), and possibly the inaccuracy of the numerical time scale(s). In fact, a recent highresolution analysis of extraterrestrial 3He through the K/T boundary at Gubbio by Mukhopadhyay et al. (1988) shows equal concentrations in the uppermost Cretaceous and lowermost Tertiary limestones, indicating practically identical sedimentation rates. In summary, on a simple sedimentological basis, we can infer a duration of the K/T clay episode longer than 15 ka and shorter than 75 ka, with a preferred, possibly more realistic, figure of 50 ka. A confirmation of this time estimate came from considerations about the authigenesis of glaucony. The glauconitic spherules, in fact, are the ones that best reveal the unusual early diagenetic environment of the K/T boundary clay. Glaucony is virtually absent in the well-oxidized, deep-water carbonate sediments of the Scaglia Rossa Formation, and was never described in any of the Jurassic to Oligocene pelagic carbonate formations of the U - M basin. At Gubbio, the first occurrence of glauconitic pellets have been reported in a few lower Miocene sandy limestones layers at the base of the Bisciaro Formation (e.g., Montanari et al. 1991). Therefore, glaucony in the thin K/T boundary clay clearly indicates an unusual diagenetic environment. Authigenic growth of glaucony at the expense of a mineral precursor, such as volcanic glass or a silicate crystal, occurs in a slightly reducing marine environment at or immediately below the water-sediment interface. Circulation of sea water in such an environment is necessary for ion exchange and glauconitization
220
(e.g., Odin and Dodson 1982). The evolution of glaucony can progress only if these conditions are met, and the growing mineral acquires from sea water more and more K20: excessive burial and restricted water circulation or a change in the Eh would stop the process. A more or less mature glaucony cannot regress to a less evolute phase but will be preserved as is or can be altered into another authigenic mineral (i.e., pyrite, goethite). On these premises, and on the basis of empirical observation of glauconitization in recent sediments, Odin and Fullagar (1988) constructed a chart of glancony evolution (i.e., K~O from 2 to 9 wt.%) versus time of formation. This relation practically indicates how long the particular low-Eh and/or ion exchange conditions in the diagenetic environment lasted before the glauconitization process is stopped by a change in water chemistry or burial isolation. In the case of the K/T glaucony, its K20 content ranging between 5 wt.% and 6.5 wt.% would indicate that the necessary low-Eh conditions for glauconitization lasted between 7 and 70 ka (Fig. 5.7.5.2). Only the bright green glancony at Contessa, among others analyzed by Montanari (1991) in the U-M basin, with a K20 content of about 7.3 wt.%, would indicate a longer duration of authigenic evolution around 100200 ka (Fig. 5.7.5.2). The interpretation by Montanari (1991) of the Italian K/T glaucony is that it was formed on the sea floor during the short lived low-Eh event immediately following the mass kill of the marine plankton. Iron-rich microkrystites would have been transformed authigenically into glaucony, whereas silica-rich ones (i.e., mostly made of quenched calcic feldspar and perhaps clinopyroxene), would have been altered into K-feldspar. The return to normal oxygenation on the sea floor would have definitively stopped the process of glauconitization. The fact that the glaucony at different levels within the K/T clay in the wellpreserved section of Petriccio (see Sect. 5.7.6) have all the same maturity led Montanari (1991) to infer that the impact spherules reached the sea floor at once, and were spread upward later while the clay was forming, perhaps by a tenuous microbioturbation activity. The end result is a peak of spherule abundance in the central part of the K/T clay layer, which is mimicked by an abundance peak of Ir. The problem with this high-resolution stratigraphic observation is that quartz grains, including shocked quartz, which are rarely larger than 100 gm, are concentrated in the basal green sole of the K/T clay layer. The decoupling of quartz grains from the peak concentration of Ir and spherules in the middle of the red part of the layer, lead Montanari (1991) to suggest that at least two impacts occurred at the K/T boundary, one on continental crust producing shocked quartz grains, and the other in the ocean yielding Ir and spherules. This strange microstratigraphic distribution, however, is different from the one found in terrestrial K/T boundary sections of the North America interior, where Bohor et al. (1987b) reported that Ir is associated with shocked quartz at the top of the boundary layer, whereas altered impact spherules are found just below the Irshocked quartz layer. Although the multiple impact scenario could still be considered an interesting, workable hypothesis, the oddities in the high-resolution stratigraphy of the K/T
221
boundary clay may be explained also with a combination of local diagenetic dissolution, vertical mixing, and remobilization. The dissolution event at the beginning of the K/T clay deposition may have concentrated the quartz and remobilized (removed) the Ir, which would explain at least half of the puzzle. More difficult to explain is the concentration of spherules in the middle part of the clay and their paucity in the green sole: the process of dissolution of the carbonate (i.e., a low pH environment at the water-sediment interface) would not affect the silicate microkrystites. Vertical mixing of the impactoclastic material by post-impact reworking may explain, at least in part, the concentration of spherules and Ir in the middle part of the boundary clay. On the other hand, it remains difficult to explain how such a reworking would have removed Ir and spherules from the basal clay, but not much of the quartz grains. In conclusion, the highresolution stratigraphy in Italy still bears unsolved problems, which could be approached by further detailed work in other well preserved K/T boundary sections throughout the U - M basin.
K20 % in glauconiticspheroidsfrom the U-M K/T boundary clay |
|
.
.
i
i
OUTCROP
Furlo Pietralata
llW
Petriccio Contessa
-'-41,--
Fornaci Quarry C.
w
Montagna dei Fiori
1~)3
I
I
I
,~ I
I
years of evolution
I
I
=1=04
'
I
I
error bars = 20 ' ' ' ' '1'05
Glauconite evolution (after Odin and Fullagar, 1988) nascent I slightly evolved I evolved K20% 3 4 5 6 -) I
I
I
I
I
I
I
I I110 6
I relict 8
Fig. 5.7.5.2. Evolution of glaucony vs. time in the U-M K/T boundary.
The return to carbonate sedimentation. The eugubina limestone layer represents the restoration of conspicuous biogenic carbonate production in the surface water of the U - M basin, and/or the preservation of it after renormalization of pH conditions on the sea floor. This event occurred several thousands to several tens of thousands of years after the impact, and, judging from the sharp and smooth surface contact between the eugubina limestone and the underlying K/T clay, it
222
seems that the return to normal carbonate production and sedimentation happened rather suddenly. The eugubina limestone, which in the U - M basin is about 40-50 cm thick, is well homogenized and usually red, indicating a significant bioturbation activity on a well-oxygenated sea floor. A subtle increase in the size of the tiny (0.06 to 0.15 ram) globigerinid tests from the bottom to the top of the layer (Luterbacher and Premoli Silva 1964), suggests that some of the original stratigraphic order has been preserved within the layer despite bioturbation and vertical mixing. Vertical mixing is also indicated by altered spherules and tests of Cretaceous planktonic foraminifers scattered within the basal 2-5 cm of the G. eugubina limestone. However, this bioturbation activity, although efficient in mixing up the slowly sedimenting biogenic carbonate, was not effective in obliterating or mixing the thin K/T boundary clay. Some large detritus-feeding organisms managed to penetrate the subbottom sediment, burrowing through the K/T clay layer, and bringing down into the white bleached top-Cretaceous limestone the red, biogenic carbonate sediment of the basal-Tertiary eugubina limestone. These organisms left numerous traces of Zoophycos and Planolites in the white layer immediately below the K/T clay (Figs. 5.7.4.6 a, b, and d). Conversely, some Planolites burrows filled with white Cretaceous sediment are found in the basal 5 cm of the eugubina limestone (Fig. 5.7.4.5b). Often these burrows contain altered spherules and chunks of green and red K/T clay (Fig. 5.7.4.6b). These observations indicate that when significant bioturbation restarted on the basal Tertiary sea floor, the low pH-low Eh event was already over: the top Cretaceous limestone was already bleached, the spherules authigenically altered, and the K/T clay oxidized to a red color. Thus, the return of conspicuous planktonic carbonate production and bottom dweller activity coincided with a return of oxidizing conditions, which would have caused the formation of goethite in some Fe-rich spherules. In the Contessa section, the initial process of glauconitization seems to have lasted longer than in other K/T sites, yielding a more evolved glaucony, and the oxygenation following the initial low-Eh event was somewhat stronger than in other cases, as it is suggested by the authigenesis of hematite instead of goethite.
5.7.6 Representative K/T Boundary Outcrops in the U-M Basin In areas where the Scaglia Rossa exhibits its most typical turbidite-free facies, an exposed section with the K/T boundary, either in a quarry face, or a cliff, or along a road cut, can be confidently recognized from a distance, even from a moving car. The boundary closely coincides with the lithologic contact between the pink limestones of the R2 member of the Scaglia Rossa, and the slightly darker, more densely bedded marly limestones of the overlying R3 member. In this colored interval, the white-bleached limestone layer of the top of the Cretaceous sticks out as a distinct marker for pointing out the K/T boundary. In areas like the Furlo basin or at Monte Cbnero, where the white layer is absent, or where the whole
223
interval is whitish, the lithologic difference between the R2 and R3 members, from more to less calcareous, can still be used to spot the boundary from a distance. In any case, the basic resources of a field geologist (mente et melleo) are sufficient to find the boundary in any other situation: a hand sample exhibiting angular tests of globotruncanids means that the boundary is somewhere up section, whereas a piece of limestone with small rounded tests of globigerinids is an arrow indicating that the K/T boundary is down section. A few tries, and the fatal boundary will be narrowed down to a hand span of outcropping rock. However, the boundary hunt may end up with some disappointment. The magic layer can be covered by dirt or vegetation, or protected by a rock-fall retention steel net, or hanging too high on the cliff or quarry face, or is sheared and tectonized, as often happens, beyond recognition. For this, we would like to end this chapter on the Italian K/T boundary by guiding a potential visitor to those outcrops in the U-M region that best represent the different "facies" described above in Sect. 5.7.3. For a matter of historical respect, we will start with the classic sections near Gubbio, where the whole story started some twenty years ago. Then we will proceed to Petriccio, where the boundary has been studied in some detail, to Frontale (at walking distance from the Geological Observatory of Coldigioco), to Furlo (no bleached white layer), and finally to Monte C6nero and Montagna dei Fiori, where the K/T clay was never oxidized to its typical red color. Gubbio. The original K/T boundary outcrop of Gubbio is located in the Bottaccione Gorge, along the Gubbio--Scheggia provincial road, just before the crossing of a Medieval aqueduct (see location map in Fig. 5.5.1, and outcrop views in Fig. 5.7.6.1a, b). Here, all the main characteristics of the typical Italian K/T boundary are well expressed, such as the white-bleached top-K limestone, the Zoophycos "acme" zone just below the boundary, the bicolor green and red boundary clay, the altered impact spherules, and the dark pink, porcellaneous eugubina limestone. A summary of the stratigraphy of the K/T interval in this section is shown in Fig. 5.7.6.2. The Bottaccione outcrop is the only one in the U-M basin that has been scanned for Ir using a closely-spaced collection of samples spanning some 10 m.y. (i.e., about 60 m of stratigraphic thickness) from the uppermost Cretaceous to the lowermost Tertiary (Alvarez et al. 1990). Several Ir peaks of 0.06-0.08 ppb over a background of 0.02 ppb have been found in a 2 m interval across the K/T boundary. These peaks are two orders of magnitude smaller than the main peak in the boundary clay, and they may be attributed to vertical mixing and reworking. In addition, this is the only section where detailed geochemical and rock magnetism analyses have been carried out in the limestones bracketing the boundary (Lowrie et al. 1990), yielding evidence that the top Cretaceous white limestone has been bleached as a consequence of reduction and dissolution of its iron mineral component. The Fe content is, in fact, lower in this layer in respect to the pink limestones above and below it, and significantly lower Fe/Si ratios indicate that this is not attributable to a decrease in detrital input, but rather to removal of iron (Fig. 5.7.6.2).
224
Despite its fame of being the representative K/T boundary in Italy, the Bottaccione K/T clay is one of the worst known in the U-M region in terms of preservation and suitability for a high-resolution microstratigraphic study. In fact, in addition to strong shearing caused by flexural slip folding, the K/T clay is here intimately contaminated by the surrounding soil. A washed residue of the clay would yield abundant secondary calcite, a conspicuous amount of sandstone grains derived from the Langhian Marnoso-Arenacea flysch, and well-preserved Miocene microfossils (Fig. 6.7.6.3). Rootlets, insect parts, seeds, shiny spherules of HFinsoluble organic matter, and other recent contaminants are also found in the clay. All this material represents practically the sand-size fraction of the soil surrounding the outcrop, and constitutes the residue of the erosion and dismantling by the Bottaccione creek of the soft Miocene formations exposed upstream along the valley (Montanari 1986). They were introduced into clay seams and fractures of the outcropping Scaglia Rossa by runoff. Abundant biotite (>0.1%o of the whole rock) and -0.1 mm nuggets of titaniferous magnetite are found in a 2 cm thick red clay layer about 2 m above the K/T boundary (Fig. 5.7.6.2). Biotite flakes and booklets are often euhedral and well preserved showing no mineral alteration in X-ray diffractograms. In addition to biotite and titano-magnetite, this thin layer contains also small crystals of apatite and zircon. Rare white mica flakes suggest that some contamination from the Marnoso-Arenacea sandstone may also have occurred here as in the K/T clay. Nevertheless, this layer, which is also present at the same stratigraphic height in the Contessa section, is clearly derived from some volcanic rock and may represent, in fact, a synsedimentary volcaniclastic event. However, preliminary fission track dating from 18 apatite grains by Odin et al. (1992) yielded a wide scatter of dates, with a mean crystal age of 93.2 -+ 2.8 Ma, which is much older than an age of about 64.5 Ma expected for this stratigraphic level. No attempts have been made yet to date the biotite with K/Ar techniques. In the Contessa Valley, not far from the Bottaccione Gorge (see location of the Contessa Highway - CH - section in Fig. 5.5.1), the boundary is well exposed on both sides of the highway, fight after the northern exit of a short rock-fall protection tunnel (Fig. 5.7.6.1b). The K/T clay here has the same problem of tectonic shearing and outcrop contamination as at Bottaccione, although somewhat less severe. The only significant difference from its twin section is that the K/T clay contains a more evolute glaucony which, as explained in the previous section of this book, would indicate that early diagenetic low-Eh conditions in this site lasted a bit longer than at Bottaccione. Moreover, strongly flattened, red hematite magnetic spheroids, which are absent in the Bottaccione and in other known K/T clay outcrops in the region, suggest that at Contessa the re-oxidation process following the initial low-Eh event was more intense than elsewhere in the U - M basin.
225
Fig. 5.7.6.1. Outcrop views of the K/T boundary in the Gubbio sections: a) Bottaccione Gorge; b) Contessa Highway (-- CH in Fig. 5.5.1).
226
BOTFACCION E E
._= Ir (ppb) O
=
.ON
Alvarez et al. (1990)
~ 0
0.1
Lowrle et al. (1990)
0.2
m
349
Fe
~
Si
Fe/Si
348 peakat 3 ppb 347
346 wt% 1
10
E
q
J
~'
34s
I_
i_ q i-
344
i- I " I -I
m
342 E
thin-bedded pink limestone red marl
~tL~ Zoophycos and Planolites traoa fossils
I ~
bleached white limestone
•
biotite-rich volcaniclastlc layer
LBI~
medlum-bedded pink limestone
bleached zone
Fig. 5.7.6.2. Stratigraphic synthesis of the K/T boundary interval at Bottaccione.
227
Fig. 5.7.6.3. The problem of outcrop contamination in the K/T section of Gubbio (from Montanari 1986). SEM images of shiny sphemles made of recent organic matter from a) the K/T boundary clay in the Bottaccione section, and b) the soil surrounding the same outcrop; c) and d) are SEM images of Miocene planktonic foraminifers and fragments of fossiliferous (FS) Langhian Marnoso-Arenacea sandstone contained in the K/T boundary clay at Bottaccione, and in the surrounding soil, respectively; e) thin section microphotograph (crossed polarizers) of loose silicate sand grains from the contaminated K/T boundary clay in the Bottaccione section obtained by dissolving in HC1 the K/T bulk layer fraction >64 gm: L = lithic fragments; Q = quartz; M = microcline; P = plagioclase; f) thin section microphotograph (crossed polarizers) of the HCl-insoluble residue >64 gm from the uncontaminated K/T boundary clay layer of Petriccio; BF arenaceous benthic foraminifer (Spiroplectammina sp.); S = sanidine-altered microkrystite; G = glauconitized microkrystite; FA = fragments of arenaceous benthic foraminifers.
228
Petriccio. The best preserved K/T boundary exposure in the U-M region with a typical "Gubbio facies", that is with a clear white-bleached top-K limestone, a relatively expanded bicolored boundary clay, and the dark pink eugubina limestone, is located on the fight bank of the Candigliano River, near the village of Petriccio, in the vicinity of Acqualagna (Fig. 5.7.6.4).
Fig. 5.7.6.4. Location map of the Petriccio section.
For many years, this outcrop has been easily accessible by wading through the shallow river from Petriccio (the decrepit suspension bridge described by Montanafi et al. 1983, is no longer practicable), or descending the fight bank along a trail from the once abandoned farm of Podrina. However, the farm has been recently reclaimed and fenced in. The passage outside and around the fence is still accessible in theory, but the property is now (t999-2000) guarded by a couple of large Rottweiler dogs, Nala and Pumba. So, in practice, given that these dogs often get loose by biting holes through the metal chickenwire fence, and that they are extremely vicious, the Petriccio section no longer has easy, safe access. Our strong recommendation for anyone who wants to visit it is to call ahead the owners of the farm, asking the courtesy of holding the dogs. The farm's masters, Mr. and Mrs. Mascarucci (Phone 0347-1192826) are kind, cooperative persons (despite their arguable canine preferences), and they both speak fluent English.
229
Fig. 5.7.6.5. Outcrop views of the K/T boundary at Petriccio, a) The K/T clay is located at the base of the overhanging eugubina limestone; b) close-up of the K/T clay layer. Note the dark trace fossils in the upper part of the white, top Cretaceous limestone.
~JD
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5
10 O
r (ppb) BULK ROCK bars = 2(~
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FINE FRACTION 99.9% of bulk rock
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0
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200
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unshocked shocked ~ / single set multipleset
per cm 3 per 10 cm z
QUARTZ GRAINS per 100 g bulk rock
SPHEROIDS
231
The Petriccio outcrop extends along the collapsed river bank for about 15 m. Bedding is subhorizontal and just slightly disturbed in a few spots by small displacement conjugate faults. The white-bleached top Cretaceous layer is clearly visible and contains numerous Zoophycos traces (Fig. 5.7.6.5a). The K/T clay layer is 20-30 mm thick, uncontaminated and relatively unsheared (Fig. 5.7.6.5b). A few Tertiary globigerinid tests less than 80 gm in size, probably introduced into the clay layer by bioturbation from the eugubina ooze, are recognizable in smear slides. The overall good preservation of the Petriccio K/T boundary outcrop allowed Montanari et al. (1983) and Montanari (1990) to perform a high-resolution microstratigraphic study of the clay, which is summarized in Fig. 5.7.6.6, and the interpretation of which is described in detail in the preceding Sect. 5.7.4. Frontale. An extended section of the Scaglia Rossa is exposed along the mountain road connecting the village of Frontale to the resort area of Pian dell'Elmo, at the foot of Monte San Vicino (Fig. 5.7.6.7). The magnetostratigraphy of this section, along with the identification of some important planktonic foraminiferal events, was determined by Chanet al. (1985; see Fig. 5.7.6.8), whereas the general sedimentology of this area was studied by Montanari al. (1989) in the context of a regional basin analysis. Fig. 5.7.6.8 reports also the stratigraphy of the close-by Poggio San Vicino section (see map in Fig. 5.7.6.7) where the inoceramid extinction event has been studied by Chauris et al. (1997), and where a significant enhancement of extraterrestrial 3He was reported by Mukhopadhyay et al. (1998) in the lower Maastrichtian (see also Sect. 5.7.1). Unfortunately, in the Poggio San Vicino section the K/T boundary was involved in a soft sediment slump and it is not resolvable. We would like to point out, however, that lithified clasts of the eugubina limestone are found at the base of a 10 cm thick turbidite resting on top of this slump. The turbidite itself is partitioned with a Ta Bauma interval at the base, which is made of large Cretaceous planktonic foraminiferal tests, and a Tb made of small Tertiary globigerinids. This would indicate that the fine-grained, porcellaneous eugubina limestone experienced an early diagenetic cementation in contrast with the enclosing Cretaceous and Tertiary pelagic muds, which were remobilized as loose sediment and sorted out during a slumping event (Alvarez et al. 1985; Montanari et al. 1989). At Frontale, the K/T boundary is exposed on a large quarry face, which offers a panoramic view of the R2-R3 interval of the Scaglia Rossa (Fig. 5.7.6.9). The white top Cretaceous limestone layer is present in this section. However, the white layer visible on the quarry face is not the top Cretaceous marker, but rather the eugubina limestone. In fact, unlike the typical "Gubbio facies", at Frontale the eugubina limestone is pink only for its basal three or four centimeters, and for the rest it is whitish. Just above the eugubina limestone, the limestones and marls of the R3 member are visibly deformed by soft-sediment slump structures which may be correlated with the slump in the nearby section of Poggio San Vicino. Above the slump interval, a few thin layers of white limestone represent very fine calcarenitic turbidites made of reworked foraminiferal tests. These turbidites are exposed also along the Frontale road cut, where the conspicuous slump structure in the lowermost Tertiary is apparently missing.
232
Poggio
N
1 km
Poggio S. vicino Section
Frontale
Quarry
rontale Fomelle,
Villanova , Plan delrEIrno
Fig. 5.7.6.7. Locationmap of the Frontale and Poggio San Vicino sections.
Approaching the K/T boundary in the quarry may be dangerous due to frequent rock falls. Moreover, a normal, synsedimentary fault in the eastern corner of the quarry makes it difficult to reach the boundary, which remains exposed some 3-4 meters above the quarry floor. On the other hand, the same boundary, lowered down by the fault, is well exposed on a small outcrop at the end of the road cut section, right at the eastern entrance of the quarry (Fig. 5.7.6.9). This outcrop has been recently cleaned and reclaimed by the Mountain Community of Monte San Vicino, which installed an illustrated explanatory panel about the K/T event. In the Frontale quarry, the limestones immediately below and above the K/T boundary clay layer are tectonically undisturbed, and free of closely spaced bedding-parallel pressure-solution stylolites, which usually disturb other K/T sites in the U-M region. On a cut surface, the gradual transition between the pink Creta-
233
ceous limestone layer, which has a total thickness of 30 cm, and the whitebleached band is located about 15 cm below the K/T boundary (Fig. 5.7.6.10a). Abundant trace fossils of Zoophycos and Planolites have diameters in the range of few millimeters, and are filled with reddish or reddish-brown basal Tertiary sediment. Occasionally, altered impact spherules are found in the burrows.
FRONTALE lithosf~'adgraphy
m
,10-
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POGGIO SAN VICINO
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5thology
planktonic events foraminif~al
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Fig. 5.7.6.8. Stratigraphic syntheses of the Frontale and Poggio San Vicino sections.
234
Fig. 5.7.6.9. Panoramic view of the Frontale Quarry (left side the photo), and of the small K/T boundary outcrop along the road cut (right side of the photo).
The basal, well-homogenized eugubina limestone layer exhibits a pink bottom, which grades upward to a whitish color some 3 - 4 c m above the base (Fig. 5.7.6.10b). Altered impact spherules are scattered in the lower 2-3 cm of the layer. Few Planolites burrows with diameters up to 5 mm, are filled with grayish Tertiary sediment. Occasional large Planolites burrows with diameters of up to 2 cm are found laying parallel to bedding in the upper part of the layer, and they are filled with white-bleached Cretaceous sediment, including some chunks of whitish and gray Tertiary sediment (Fig. 5.7.6.10b).
235
Fig. 5.7.6.10. a) Polished slab of the top, bleached Cretaceous layer at Frontale. Note the worm burrows filled with dark eugubina ooze. b) Polished slab of the basal eugubina limestone. Note the color transition from pink to white at the base of the layer, and the large worm burrow filled with white ooze derived from the bleached top Cretaceous limestone layer. The small divisions of the rulers in pictures a) and b) are millimeters.
The 15-20 m m thick K/T clay exhibits its thin basal green sole, as at Gubbio and Petriccio, and it is fairly well preserved being almost free of tectonic shearing and secondary calcite. The most peculiar aspect of this boundary in contrast with other K/T clays studied in the region, is that it contains frequent, moderately wellpreserved tests of Cretaceous and lowermost Tertiary planktonic foraminifers (Fig. 5.7.6.1 la, b). These fossils were probably introduced into the clay by post-P0 bioturbation. This is suggested by the fact that the burrows in the top Cretaceous limestone are never exclusively filled with G. cretacea tests, but they contain tests of G. eugubina, G. fringa, G. minutula, and W. hornestowensis, which would indicate a P1 Zone source (Montanari 1990).
236
Fig. 5.7.6.11. a) SEM image of large Cretaceous planktonic foraminiferal tests (upper part of the image) and small basal Tertiary globigerinids (center of the image) extracted from the K/T boundary clay of Frontale. The good preservation of these reworked planktonic foraminiferal tests contrasts with the poor preservation of authochthon benthic foraminifers which exhibit clear signs of corrosion (see the four tests in the lower part of the image). Scale bar = 0.5 mm. b) Smear slide microphotograph (transmitted, plain light) of basal Tertiary globigerinids from the Frontale K/T clay. Note also the well-preserved fish tooth in the center of the photo. Tooth length approximately 0.05 mm.
The reasons why these microfossils are abundant in the Frontale K/T clay (and in a few other sections such as Cingoli and Ceselli; see Luterbacher and Premoli Silva 1964, and Montanari 1990), and not in other strongly bioturbated sections such as Furlo, remains unclear. The green sole adhering over a corroded topCretaceous, white-bleached limestone, and the clearly corroded tests of robust calcareous benthic foraminifers (Fig. 5.7.6.1 la) indicate that also at Frontale the brief episode of low-pH and low-Eh conditions occurred during the deposition of the K/T clay. On the other hand, the burrows filled with red lowermost Tertiary sediment penetrating the top-Cretaceous limestone, along with the red base of the G. eugubina limestone, indicate that a return to normal oxidizing conditions coincided with the restoration of copious carbonate production and sedimentation.
237
Perhaps at other U - M sites the dissolution of delicate planktonic foraminiferal tests occurred at a later diagenetic phase. Furlo. The Scaglia Rossa Formation in the anticlinal structure of Monte Paganuccio-Monte Pietralata, which is cut by the picturesque Furlo Gorge, exhibits a sedimentary facies different from that of the classic area of Gubbio. Here, the typically pink pelagic biomicrites, starting in the upper Santonian R1 member all the way up to the Paleocene R3 member, are interbedded with white foraminiferal turbidites. The magnetic stratigraphy of the upper Cretaceous-lower Tertiary Furlo sequence was determined by Alvarez and Lowrie (1984) and Chan et al. (1985), while a detailed basin and paleocurrent analysis of the Scaglia Rossa was carried out by Montanari et al. (1989). A stratigraphic synthesis of the Furlo sequence is shown in Fig. 5.7.6.12. The Furlo area represented an intrabasinal depocenter, which started to subside in the Turonian, following a rejuvenated regional extensional tectonic phase (see Chap. 4 and Fig. 4.2). The white turbidites, probably triggered by earthquakes, are typically partitioned with Tb and Tc Bauma intervals, and are essentially made of reworked planktonic foraminiferal tests, which were sorted in turbidity currents of remobilized intraformational pelagic sediment. Through the R2 and lower R3 members of the Scaglia Rossa, these turbidites are arranged into two main thickening-up cycles, the lower culminating with a conspicuous turbidite marker made of three (or sometimes two, like at Pietralata) amalgamated units called the "triple turbidite" (TripleT), and the upper cycle ending with a 1 m thick turbidite called the "mega turbidite" (MegaT). The inoceramid abundance peak and extinction event, described in Sect. 5.7.1 of this book, is located just below the TripleT marker, and it can be easily found in several outcrops and in abandoned quarries along the road that from Furlo climbs up toward the top of the mountain (see map in Fig. 5.6.1). The K/T boundary happens to be located in the upper part of the second cycle, about seven meters below the MegaT. The boundary is bracketed by two couples of turbidites, and it is overlain by a 2-m-thick interval of thin-bedded, dark pink platy limestones representing the lowermost Tertiary (Fig. 5.7.6.12). Among the many good outcrops of the K/T boundary interval known in the Furlo area, the Pietralata section is perhaps the best exposed and most easy to reach. The outcrop is located along a mountain road past the church of Pietralata (see map in Fig. 5.6.1 and panoramic view in Fig. 5.7.6.13a). A characteristic of this K/T boundary that catches the eye at first sight is the intense bioturbation decorating the top, light pink limestone of the Cretaceous (Fig. 5.7.6.13b).
238
FURLO lithostratigraphy
m!
Pietralata seclJon
Upper Road
~.
section turbidite thiclmess 0 om 100
turbidite thictmess
R4 300 -
_<
T K
_¢j~
R3
250 -
0
TripleT
Tdp~eT
TripleT I --
-I~
-
MegaT
R2
100-
200-
tJegaT ,• ~ • L
r~--
slump
<~" R2m
..-I
Z ¢
150 -
-Q~
hJ_rL_~
S
slump
z ~
<
s with chert
slur~
= R1
100 -
.=stones
~ sl"mp z
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~
slump
X
50-
~
slump
I
slump
Z Z ~
-
Bonarelll
SCAGLIA BIANCA
'r
6~ E
Fig. 5.7.6.12. Stratigraphic synthesis of the Scaglia Rossa sequence at Furlo.
239
Numerous traces of Planolites and Zoophycos, large and small, are filled with dark pink sediment, and penetrate the top Cretaceous limestone for 20-30 cm below the boundary clay. The microfossils filling the burrows are the tiny globigerinids found in the first Tertiary limestone, but larger Cretaceous microfossils, as well as lowermost Tertiary tests belonging to the upper G. eugubina Zone, are also found in the burrows (Fig. 5.7.4.6). As for the actual basal Tertiary, it also appears strongly bioturbated. Reworked tests of Cretaceous foraminifers are much more abundant here than in any other K/T boundary site in the region. Altered spherules and occasional pieces of boundary clay are also found in the burrows below the boundary, and sparse in the basal portion of the Tertiary limestone. The strong bioturbation and vertical mixing characterizing the Furlo K/T boundary is probably the result of good oxygenation of the sea floor, which was frequently swept by bottom currents in this area of the U - M basin. Winnowing is also the probable reason for a strongly condensed basal Tertiary, which represents a total accumulation rate of 1-2 mm/ka, which is a factor of 3-5 slower than at Gubbio (Alvarez and Lowrie 1994). Despite these particular sedimentological conditions, the 8 mm thick K/T clay layer is still preserved here, although it lacks the typical green sole, and contains an unusually low concentration of Ir (1-2 ppb) compared with other sites in the region. As mentioned in the preceding chapter of this book, winnowing may have removed some of the K/T clay, and even the lowEh film of stagnating water at the water-sediment interface. However, temporary redox conditions favoring the authigenesis of glaucony must have occurred here as in any other site in the U - M basin, as it is demonstrated by the presence of altered glauconitic impact spherules. Monte Cbnero. The Monte C6nero promontory is the easternmost anticline of the northern Apennine thrust-and-fold belt (Fig. 4.1.1). The U - M carbonate sequence is here exposed from the middle part of the Maiolica Formation all the way up to the Schlier Formation which, in this area, reaches the very top of the Tortonian and is, therefore, laterally heteropic with the flysch formations of the Marnoso-Arenacea and the Laga exposed elsewhere in the U - M Apennines (see Chap. 4). The sedimentary facies of the Scaglia Rossa at Monte C6nero is different from the equivalent unit of the classic Gubbio sequence. First of all, the Cretaceous portion of this formation exhibits a whitish-yellowish color instead of the typical pink of the U - M facies, and secondly, coccolith-foraminiferal biomicrites are interbedded with white calcarenitic and calciruditic turbidites derived from a carbonate platform, which was located not far to the east of the present C6nero area. Thus, the Scaglia Rossa represents here a proximal facies characterized by lobate and strongly channelized carbonate turbidites and grain flows interfingering, at the toe of a carbonate apron (Colacicchi and Baldanza 1986), with the pelagic muds of the U - M deep-water basin (Montanari et al. 1989).
240
Fig. 5.7.6.13. a) Panoramic view of the K/T boundary outcrop at Pietralata. b) Close-up of the K/T boundary at Pietralata. Note the numerous, dark colored burrows (P = Planolites; Z = Zoophycos) in the top Cretaceous limestone.
The K/T boundary is exposed in numerous localities in the Cbnero area, but the best sections can be found in the quarries of Fornaci, near the village of Poggio, and at Fonte d'Olio, near the town of Sirolo (Fig. 5.7.6.14). The biostratigraphy of
241
the interval covering the boundary was originally defined by Luterbacher and Premoli Silva (1964), and only recently restudied in several sections at Fornaci and Fonte d'Olio by Casoni (1988) and Mazzanti (1988). A stratigraphic synthesis and correlation among the most representative of these sections is shown in Fig. 5.7.6.15. The K/T boundary is located about 80 cm below a 2-3 m thick calcirudite marker bed called "Mega T" by Montanari et al. (1989), or "Marchesini Level" by Coccioni et al. (1994), and is marked by a 18 mm greenish clay layer sandwiched between pelagic limestones. Apart from their whitish or creamy color, the texture and microfacies of the top Cretaceous mayaroensis limestone, and the basal Tertiary, porcellaneous eugubina limestone are identical to those seen in other U-M sections. These light colors are due to a relatively more reduced state of the paleosea floor compared to the well-oxygenated environments expressed by the typically pink Scaglia Rossa. Higher plankton productivity and upwelling in this proximal environment may have been the main reasons for more reduced conditions on the sea floor in respect to other open sea, deeper areas of the paleobasin. The spectacular exposures in the Fornaci quarry offer the possibility to follow the K/T boundary along strike for about 500 m. In the west side of the quarry (Fig. 5.7.6.16a), the MegaT and the K/T boundary below it are well visible although it may be dangerous to approach the quarry face due to frequent rock falls. In this part of Monte C6nero, the typical pink color of the Scaglia Rossa reappears in the lower part of the R3 member, a few meters above the MegaT. The higher level of the central sector of the quarry offers a safer and more approachable exposure of the uppermost part of the Cretaceous. This section can be reached following a trail hidden in the thicket, and departing from the east end of the quarry. Here the calcarenitic turbidites appear strongly channelized, and in some cases they show a convex upper surface indicating a lobate geometry of these detrital bodies. A closer look at these calcareous turbidites reveals a granular texture made of biogenic debris including large benthic foraminifers (orbitoids), rudist fragments, calcareous algae, echinoid spines, pieces of corals, and lithoclasts of pre-existing shallow water limestones. These detritic layers are found below and above the K/T boundary, and may represent excellent material for studying the biofacies evolution of the western Adriatic platform which was completely dismantled after the K/T event. In simpler words, they may function as messengers of an evolving, and eventually killed platform, the incomplete remnant of which is now buried under the Adriatic Sea floor. In fact, large flute casts and inclined laminations indicate a preferential paleocurrent flow from eastern toward western quadrants. Some large flutes with different shapes (i.e., bulb, tongue, curl) are visible at the base of some MegaT boulders piled up at the edge of the quarry rim. The MegaT and the underlying K/T boundary are exposed on a ledge at the very top of this outcrop.
242
b
, Bar
Massignano
Fonte d'Olio
N Sirolo 1 km
Fig. 5.7.6.14. Location map of the Monte Cbnero K/T and E/O sections described in the text.
243
MONTE CbNERO LITHOSTRATtGRAPHY AND SECTION Fornaci Wast
Fomaci Central
PLANKTONIC I FO~MINIFERAL AGE BIOSTRAT GRAPHY
Fomaci East
Fonte d'Olio
event
Zone
p. pus//~a
P3
.~pusi#a M. angula~e
110
>. t~ .J P. chapmani
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,'N',
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o
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i
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marly limestone
1 G. ~m/cata
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i
~
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Fig. 5.7.6.15. Stratigraphy of four representative sections in the Cbnero area, covering the K/T boundary. Lithostratigraphy after Montanari (1979); Cretaceous biostratigraphy after Mazzanti (1988); Tertiary biostratigraphy after Casoni (1988).
244
At the base of the trail, now hidden behind a thick grove of young pine trees, there is an interesting exposure of the K/T boundary on the easternmost face of the quarry. The boundary is located up high on the quarry face and can be reached with a ladder (Fig. 5.7.6.16b). The peculiar aspect of this outcrop is that the MegaT is here reduced to a 10 cm thin, discontinuous calcarenitic layer. The lower R3 member of the Scaglia Rossa in this outcrop exhibits its typical dark pink, marly facies. This exposure is topped by another thick calcarenitic turbidite very similar to the MegaT which is not present in the Fornaci West section, a further demonstration of the strongly channelized geometry of these detrital bodies. The best and most approachable exposure of the K/T boundary in the C6nero area is located in the upper ledge of the so-called Quagliotti quarry in the Fonte d'Olio valley (see location map in Fig. 5.7.6.14 and outcrop panoramic in Fig. 5.7.6.17a). This outcrop can be reached following, for a short distance, a trail departing from a forest road near a resort facility half way up along the Fonte d'Olio-Monte C6nero main road. Here, the K/T boundary exhibits the exact same facies as in the Fornaci West and Central quarries, and is located at practically the same distance (about 80 cm) below the MegaT (Fig. 5.7.6.17b). However, the Tertiary Scaglia shows a whitish-yellowish color, indicating that in this part of the C6nero basin, relatively reduced conditions on the sea floor lasted for several million years after the K/T event. The clay layer has a green-ochre color and is, therefore, different from the same (red) layer observed at Gubbio and Furlo, and anywhere else in the UmbriaMarche basin. More reducing conditions of the paleosea floor are also indicated by the fact that goethite spherules are absent in this K/T boundary layer. Only altered microkrystites made of slightly evolved, pale-green glaucony, and Kfeldspar are present, along with shocked quartz grains, and well differentiated arenaceous benthonic foraminifers, which are somewhat larger than those found in other K/T boundary layers in the region. Moreover, the boundary clay contains 10 ppb Ir, the largest anomaly measured in the U-M basin (Montanari 1990). Trace fossils in the whitish top Cretaceous limestone are very thin and scarce compared to other U-M K/T sites. They are mostly concentrated in the uppermost 10 cm of the layer, and filled with eugubina sediment. The top surface of this layer also shows evidence of corrosion, as in the most typical K/T boundary sites in the U-M region. The eugubina limestone, which has a light ochre color, and a reduced thickness of 22 cm (Mazzanti 1988), is thoroughly homogenized by bioturbation, although discrete trace fossils are seldom visible. The lower part of the layer contains frequent reworked Cretaceous foraminiferal tests and fragments of altered impact spheroids.
245
Fig. 5.7.6.16. a) Panoramic view of the K/T interval exposed in the Fomaci West quarry face. b) Panoramic view of the K/T interval in the Fomaci East quarry face. Note the absence of the MegaT marker above the K/T boundary. Y = yellowish; P = pink; W = white; K = Cretaceous; T = Tertiary; MT = MegaT marker.
246
Fig. 5.7.6.17. a) Panoramic view of the Quagliotti quarry near Fonte d'Olio. The K/T boundary is located about 80 cm below the 2 m thick MegaT marker, b) Close-up of the K/T interval in the Quagliotti quarry outcrop.
247
Montagna dei Fiori. In the Montagna dei Fiori area, like at Monte Cbnero, the R2 and R3 members of the Scaglia Rossa exhibit a relatively proximal facies characterized by frequent and thick calcarenitic turbidites (Crescenti 1969; Montanari et al. 1989). These turbidites are made of calcareous debris derived from the margins of the Abruzzi carbonate platform located not far to the south. As at Monte Cbnero, the biomicritic, pelagic limestones interbedded with the turbidites have a whitish color, whereas the typical pink color of the Scaglia Rossa can be seen only in the lower and upper members of this formation. Thin and very fine calcarenitic turbidites are found also in the Scaglia Bianca Formation, and they are usually associated with black tabular chert layers. The Bonarelli Level, at the Cenomanian-Turonian boundary, has a reduced thickness of 60 cm, but its lithology and internal stratigraphy is practically identical to those of the typical Bonarelli marker exposed anywhere else in the U-M Apennines.
Fig. 5.7.6.18. Locationmap of the K/T boundarysection in the Montagnadei Fiori area.
The K/T boundary is located in a pelagic interval, on a section stretching along the road that leads from the village of Garrufo up to the remote village of Macchia di Sole (see map in Fig. 5.7.6.18). The outcrop in the region of the K/T boundary is strongly tectonized and it cannot be used for a high-resolution stratigraphical study (Fig. 5.7.6.19a, b). Despite strong shearing, this outcrop yields interesting
248
information about the particular sedimentary environment in this part of the paleobasin at the time of the K/T boundary event. First of all, the limestones just above and below the K/T boundary are white indicating low oxygen conditions at the water-sediment interface prior and after the K/T event. The K/T clay is green and practically barren of benthic foraminifers (only a few broken pieces of Ammodiscus were found by Montanari 1990). Moreover, K-feldspar and goethite impact spheroids are absent in this clay.
Fig. 5.7.6.19. a) Panoramic view of the Monte dei Fiori section containing the K/T boundary, b) Close-up of the strongly tectonized K/T interval in the same section.
249
Instead, euhedral grains of pyrite make up nearly 90% of the HCl-insoluble sand-size fraction of the clay (Fig. 5.7.6.20), while the rest is made up by evolved glaucony. These observations indicate that the environment during the deposition of the K/T clay was strongly reducing, to the point of suppressing benthic life, and allowing authigenic growth of iron sulfide.
Fig. 5.7.6.20. SEM image of euhedral pyrite from the K/T boundary clay of the Montagna dei Fiori outcrop.
250
5.8 The Paleogene Impact Record The diagram of impact energy flux in Fig. 5.1.2 shows two prominent peaks in the Paleogene, the smaller one at the base of the Eocene (i.e., around 52-54 Ma), and the larger in the Late Eocene (-36 Ma). At present there are no known large impact craters, nor prominent peaks of marine extinctions with Oligocene ages, in the Sepkoski (1996) analysis. Therefore, in this chapter we will focus on the U - M record across the Paleocene-Eocene (P/E) boundary and the Late Eocene, which are both well represented in several outcrops of undisturbed, pelagic sediments near the intraformational boundaries between the Scaglia Rossa, Scaglia Variegata, and Scaglia Cinerea formations, respectively. The most continuous exposure of the Paleogene in the U - M Apennines stretches along road cuts and quarries in the Contessa Valley near Gubbio (see location map in Fig. 5.5.1). An integrated stratigraphic synthesis of this sequence, from the K/T to the Eocene-Oligocene boundaries, is shown in Fig. 5.8.1, along with radioisotopic age tie points, which permit to calibrate the whole sequence by interpolation. This figure reports also the ages and sizes of the largest craters known in this time span. The age uncertainty of the impact events can be directly projected against the stratigraphy of the Contessa sequence, permitting the narrowing down of discrete outcrop intervals that may contain the signatures of these impact events. The discussion and illustration of known information on impact signatures will be given separately for the Paleocene-Eocene, and the terminal Eocene intervals in the following chapters.
5.8.1 The Paleocene-Eocene Boundary Whereas the integrated stratigraphy across the E/O boundary in the U - M region has been studied in great detail, and impactoclastic signatures have been found in the upper Eocene portion of this interval (see Sect. 5.8.2), to our knowledge no studies have ever focused on impact stratigraphy across the Paleocene-Eocene (P/E) boundary. Also for this interval, the nearly complete and continuous pelagic sequence of Gubbio may offer the rare opportunity to approach the investigation of impact signatures and/or the effects they may have had on the marine biota, which is here represented by an excellent microfossil record. Although no prominent peak of extinction in marine genera shows up in Sepkoski's (1996) diagram (see Fig. 5.1.1), the P/E boundary has been the focus of recent detailed studies, because, in fact, it records the sudden extinction of up to 50% benthic foraminiferal species in the southern oceans (Thomas 1990; Kennett and Stott 1991), as well as in higher latitude oceans (Douglas and Woodruff 1981; Tjalsma and Lohman 1993; Kaiho 1991), and the Tethys (Ortiz 1994; Speijer 1994). This extinction event seems to have affected only bathyal and abyssal environments, and coincides with a sharp negative shift of the 613C record.
251
The extinction event occurs in a very narrow stratigraphic interval in nannofossil Zone CP8 (i.e., around 55 Ma), which may represent a few tens of thousand years (Thomas 1990), or as little as 3,000 years (Kennett and Stott 1991). This event is apparently not coupled to extinctions or drastic turnovers in the planktonic realm. It is widely accepted that a global climatic change following a gradual warming of Antarctic surface waters at a time when Antarctica was not yet glaciated, would have decreased the temperature difference between surface and deep waters in all the oceans, significantly slowing down the thermally driven oceanic water circulation. This may have caused dysoxia in deep water environments, which would have affected the benthic community. However, the sudden and drastic benthic extinction at the P/E boundary would have required an equally sudden and shortlived climatic or environmental global event not necessarily consequent to the ongoing, gradual climatic change during this period of time. Eldholm and Thomas (1993) proposed that CO 2 produced by North Atlantic volcanism would have raised surface water temperatures at high latitudes, causing rapid water circulation and environmental changes throughout the world. However, no increase in atmospheric CO 2 could be deduced from the geochemistry of organic matter and carbonate of late Paleocene-early Eocene terrestrial sediments in the Paris Basin analyzed by Sinha and Stott (1994). Therefore, the cause of the sudden event at the P/E boundary remains a mystery, but see Katz et al. (1999) and Norris and Kthl (1999) for an interesting new proposal. At Gubbio, the upper Paleocene-Early Eocene interval is exposed along the Contessa Road section (the CR section in location map of Fig. 5.5.1; see also panoramic view in Fig. 5.8.1.1) the magneto- and biostratigraphy of which have been defined by Lowrie et al. (1982) and Monechi and Tierstein (1985). The boundary is found in the upper part of the Scaglia Rossa R3 member (chert-free, marls and marly limestones). The color of these carbonate rocks is dark pink, indicating a well-oxygenated deep-water environment. High-resolution magnetostratigraphic, micropaleontologic, geochemical, and paleoecologic studies across this boundary in the CR section are now in progress by a team of interdisciplinary researchers (Galeotti et al. 1988), and we are confident that new information will be produced by this team effort, which will certainly contribute to a better understanding of the changes occurring during this interesting episode of Earth's history. Following the objective of this book, we may ask the question whether the P/E climatic and ecologic events might be related to extraterrestrial causes. The four or five impact craters known through this span of time are too small to be considered effective causes of global change. The l~rgest of them is the Montagnais structure with a diameter of about 45 kin, and an age of 50.5 -+ 0.8 Ma, which is closely spaced in time with the Kamensk impact crater (25 km diameter; 49.2 + 0.2 Ma). These impacts are about 5-6 Ma younger than the P/E benthic extinction and the associated 8~3C shift. Moreover, it appears that not even in areas close to the ground zero of the Montagnais crater the microfossil record shows any sign of extinction or evolutionary discontinuity (Aubry et al. 1990).
252
I N T E G R A T E D S T R A T I G R A P H Y O F THE PALEOCENE-EOCENE PELAGIC S E Q U E N C E O F THE U-M A P E N N I N E S (METER LEVEL REFERRED T O THE C O N T E S S A CH SECTION) RADIOISOTOPIC CALIBRATION POINT
Ma
STRUCTURE IMPACT
m
LR~O Z STRATIGRAPHY ~ lithology formalion ~
CALCAREOUS PLANKTON BJOSTRATOGRApHY P19s CP 16C
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253
Fig. 5.8.1.1. Panoramic view of the Contessa Road (CR) section containing the Paleocene-Eocene boundary, which is located about 5 m below the first chert layer of the Scaglia Rossa R4 member, near the base of the marly interval in the middle of this outcrop.
As a working hypothesis, it may be considered that the nearly coeval Kamensk and Montagnais impacts are part of a comet shower, such as the one which has been inferred in the Late Eocene (Farley et al. 1988; see next chapter), and possibly in the lower-mid Maastrichtian (see Sect. 5.7.1). In fact, Farley (1995) reported a significant increase of extraterrestrial 3He through the lower Eocene in a Giant Piston Core in the central North Pacific. However, a hypothetical comet shower in the lower Eocene would be much younger than the benthic extinction at the P/E boundary and, therefore, can not be considered as a cause for this biotic crisis. Nevertheless, the particularly favorable stratigraphic qualities of the Contessa CR section constitute certainly a strong invitation to approach highresolution investigations on the impact record of this critical interval of geologic time.
<--- Fig. 5.8.1. Integrated stratigraphic synthesis of the Paleocene-Eocene Contessa Highway (CH) section, and locations of major impact events. The age of the impact glass from Beloc and Mimbral is from Swisher et al. (1991). Radioisotopic age tie points of Agost (biotite-rich volcanic ash), Greenland (basaltic spherules), and DSDP 516F (biotite-rich volcanic ash) are from Montanari and Swisher (1994). The ages of biotite-rich volcanic ashes from Massignano and Contessa are from Montanari etal. (1988b). Bio- and magnetostratigraphy, and simplified lithostratigraphy, are from Lowrie et al. (1982) and Monechi and Thierstein (1985).
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5.8.2 The Terminal Eocene Events In the years immediately following the publication by Alvarez et al. (1980) of the hypothesis that the impact of a giant extraterrestrial object was the cause of the K/T boundary mass extinction, an obvious question crossed the mind of those researchers who found such a hypothesis at least interesting: are there other mass extinction events throughout Earth's history that could be related to impacts? It was with this question in mind that Alvarez et al. (1982) undertook a trace element geochemical investigation across two interesting stratigraphical boundaries, namely the Permian-Triassic (PFFR), and the Eocene-Oligocene (E/O). The first records the most severe Phanerozoic mass extinction, whereas near the latter, in some Caribbean and Gulf of Mexico deep sea cores, glassy microspherules were known to exist, and they were already recognized as impactoclastic material (e.g., Glass et al. 1973; Maurrasse and Glass 1976; Glass and Zwart 1979). Moreover, with the first compilation and analysis of a data base and the plotting of marine families extinction rates through the past 250 Ma, Raup and Sepkoski (1982) showed that, in addition to the K/T boundary, there were some other ten statistically significant extinction peaks through this span of Earth history, and one of them was, in fact, at or near the E/O boundary. While the P/TR boundary yielded no Ir anomaly, the samples from the microspherule layer near the E/O boundary contained up to 0.4 ppb Ir. This was one order of magnitude less than the K/T boundary, but undoubtedly a strong indication that an anomalous accretion of extraterrestrial matter occurred at that time (Alvarez et al. 1982). These coincidences (Ir, microspherules, and mass extinction) were rendered even more intriguing by the fact that the largest impact structure in the past 250 Ma record known on Earth in the early 1980s was the 100 km diameter Popigai crater, in central Arctic Siberia (see compilation by Grieve 1982). Early radioisotopic dates gave an imprecise age of 39 _+9 Ma for the Popigai structure, covering the long stratigraphic interval between the Middle Eocene to the Early Oligocene. The whole picture of the terminal Eocene events in the early 1980s was somewhat out of focus compared to the controversial, but undoubtedly exciting, emerging story of the K/T boundary. That the Late Eocene was a time of major change in Earth's history was felt by many researchers (see Pomerol and Premoli Silva 1986). During the Eocene, the separation of Antarctica from the southern continents led to the formation of the circum-Antarctic current and the gradual glaciation of the continent. As the Antarctic polar ice cap spread until reaching the ocean, cold water masses formed along the continent's coasts. Being denser than warmer surface waters, these cold water masses started to sink moving away from the isolated continent for long distances toward North, eventually changing water circulation and temperature in the Earth's oceans. With time, the glaciation and a renewed oceanic circulation affected climate. Climatic cooling began to affect productivity of abyssal organisms as well as the plankton, and eventually altered the equilibrium of the global ecosystem.
255
The global cooling model, so strongly supported by geologic, geochemical, and tectonic evidence, was a classical example of gradualism, which could stand by itself, and explain the observed global changes without having to invoke a catastrophic extraterrestrial event. Moreover, there was neither any discrete boundary clay nor a dramatic extinction of dinosaurs (or of anything else) across the E/O boundary that could really attract the attention of the earth science community toward a possible extraterrestrial cause (or co-cause) for these events. And yet, impact evidence near the boundary were already available since the early 1970s. This was enough to encourage a few researchers to investigate further on these impact signatures. One of the most prohibitive factors against a prompt development of research on the possible cause-and-effect relationship between impacts and mass extinction near the E/O boundary was, since the very beginning, a somewhat confusing stratigraphic and geochronologic calibration of this time interval. In fact, ages ranging between 36 and 34 Ma for the North American tektites (see Sect. 2.4.5.1), to which the Caribbean and Gulf of Mexico microtektites are related (Chao 1973; Glass et al. 1973), were determined by fission track and K/Ar datings by a number of researchers (e.g., Zfihringer 1963; Fleischer and Price 1964; Garlick et al. 1971; Storzer et al. 1973). On the basis of biomarkers, the microtektites in Caribbean and Gulf of Mexico cores were assigned to the upper Eocene NP18 (nannofossil) Zone or to the P15 (foraminiferal) Zone in some cores, and to the NP19 Zone or P16 Zone in others. Further accurate 4°Arp9Ar dating of microtektites and tektite fragments from a land-based section in Barbados yielded an age of 35.4 + 0.6 (Glass et al. 1986b). The confusion was that the chronostratigraphic time scales most used in the early 1980s were assigning an age around 37 Ma to the E/O boundary (e.g., Berggren et al. 1978, 1985) and, therefore, they were in contrast with an age of 34.7-36 Ma for the microtektites, which were apparently contained in upper Eocene sediments. In other words, on the basis of geochronology the impact that generated the tektites and microtektites occurred in the lower Oligocene, but microfossils associated with them indicated an upper Eocene age. Such stratigraphic and geochronologic uncertainties did not help in searching for the needle in the haystack. Precise and accurate means for world wide time correlation are the sine q u a n o n for assessing the uniqueness of a sudden event such as an impact, and locate it within the stratigraphic-paleontologic record. Moreover, the time correlation between marine sediments and an impact crater, upon which any kind of inference on a possible cause-and-effect relationship can be drawn, has to be based on numerical geochronology, and, therefore, on a reliable radioisotopic calibration of the time scale. The problem lies in the fact that marine sediments are rarely dated by radioisotopic means, just as impact rocks are rarely dated by biostratigraphic means. The U-M sequence, once again, offered the unique opportunity to untangle the apparent geochronologic paradox of the E/O boundary. In fact, Lowrie et al. (1982) reported the presence of several biotite-rich layers interbedded with the pelagic marly limestones of the Scaglia Variegata-Scaglia Cinerea sequence in the Contessa Quarry (CQ) section. These discrete layers represented the fallout of
256
material erupted from distant volcanoes and, thus, they could be used to date directly, by radioisotopic means, the sediments covering the biostratigraphically and magnetostratigraphically calibrated Eocene-Oligocene interval (Lowrie etal. 1982). Early K/Ar dates from two biotite layers bracketing the E/O boundary at Contessa yielded an interpolated age for the boundary younger than 35 Ma (Montanari 1983). Further K/Ar, Rb/Sr, and 4°Ar/39Ar dating on other biotite layers from the sections of Contessa, the Monte Cagndro (near Piobbico), and the Massignano (at Monte C6nero near Ancona; Montanari et al. 1985, 1988b; Odin et al. 1988; Deino et al. 1988), corroborated by detailed geochemical and mineralogical analyses of the biotite used for these datings (Montanari et al. 1988b; Montanari 1988b; Odin et al. 1991), finally lead to a precise and accurate interpolated radioisotopic age for the E/O boundary of 33.7 + 0.4 Ma. This new age determination lowered the dates in use in the 1980s by as much as 3 Ma, and undoubtedly placed the North American tektite strewn field in the upper Eocene. Whereas a great effort was made by a number of researchers to resolve the integrated stratigraphy of the E/O boundary in the Apennines (e.g., Premoli Silva et al. 1988), investigations focused on impact spherules and Ir anomalies in deepsea cores revealed the presence of several (at least two, and possibly four) impactoclastic layers in upper Eocene sediments throughout the world. First of all, it soon became clear that in Caribbean and Gulf of Mexico cores there were not one, but two closely spaced microspherule layers (see Sect. 3.3): the older one contained clinopyroxene-bearing microkrystites, and the younger one only the crystalfree microtektites (Glass et al. 1985). Iridium was found associated with the microkrystite layer in several sections in the Caribbean-Gulf of Mexico area, as well as in the Pacific and Indian oceans, whereas the microtektite strewn field, with little or no Ir, was seemingly confined within the Caribbean, Gulf of Mexico, and northwestern Atlantic areas (Keller et al. 1983, 1987). Shocked quartz and coesite were found to be associated with this Ir-free, microtektite layer (Glass 1987; Bohor et al. 1988; Glass and Wu 1993). In addition to the closely spaced spherule layers (about 20 ka apart) in the Globorotalia cerroazulensis Zone (i.e., the P16 Zone), Keller et al. (1983b, 1987) reported an older microkrystite layer, also associated with Ir, in the upper part of the Globigerinateka semiinvoluta Zone (i.e., the P15 Zone) in equatorial Pacific and Indian Ocean sites. This finding was questioned by Glass and Burns (1987), who argued that the biostratigraphic determination by Keller and co-workers was faulty due to reworking of critical index fossils. Hazel (1989) used the graphic correlation technique on available biostratigraphic data to determine the stratigraphic position of iridium anomalies and microspherule layers in sections from the North Atlantic, Barbados, Venezuela Basin, Gulf of Mexico, central and western equatorial Pacific, and eastern equatorial Indian Ocean. He proposed at least six microspherule layers in the upper Eocene, three of which were restricted to the eastern American region, and the other three in the equatorial Indo-Pacific region. According to Hazel (1989), all of the Late Eocene microspherule layers studied occur in the G. semiinvoluta Zone.
257
In contrast, Glass (1990) argued that petrographic and compositional data indicate two, or at most four upper Eocene microspherule layers: two closely spaced layers with microkrystites and microtektites in the G. cerroazulensis Zone, and possibly two similar layers in the G. semiinvoluta Zone (as represented in DSDP Site 612). This conclusion (only two layers) was reinforced by Glass and Koebefl (1999) in their study of ODP 689B core samples. Late Eocene sediments in Core 21-5 of DSDP 612, in the north Atlantic off New Jersey, contain two spherule-bearing layers separated by -5 cm. The lower layer is represented mainly by microkrystites, although it contains also tektite fragments, whereas the upper layer contains only microtektites and tektite fragments. These microspherule layers were attributed to the G. semiinvoluta Zone by Miller et al. (1991), rather than the G. cerroazulensis Zone, in which microtektites and tektite fragments are found at Barbados (Saunders et al. 1984). However, the chemistry of tektite glass in DSDP 612 is almost identical to that of the Barbados section (D'Hondt et al. 1987; Koebefl 1988; Koeberl and Glass 1988; Stecher et al. 1989; Glass 1990). Moreover, a 4°ArPgAr plateau age of 35.5 + 0.3 Ma for the tektitic glass in DSDP 612 (Obradovich et al. 1989) is comparable to a 4°Ar/39Ar age of 35.4 _+0.6 Ma obtained from tektite fragments and microtektites from the Bath Cliff section in Barbados (Glass et al. 1986b). However, the analytical uncertainty of these dates does not permit to discern whether or not they are the same impactoclastic material or rather different impactoclastic events closely spaced in time. Miller et al. (1991) advanced the hypothesis that the Barbados and DSDP 612 tektites represent different impact events separated by -0.5-1.0 Ma, in the upper G. semiinvoluta Zone, and the middle of G. cerroazulensis Zone. As an alternative hypothesis, Miller et al. (1991) proposed that tektite glass in the two sites was produced by the same impact event within the G. cerroazulensis Zone, and that very high sedimentation rates at DSDP 612, and diachroneity of biomarkers defining zonal boundaries in the Late Eocene, would make them appear as two different events. With this background of confusing information on how many impacts, and of which age, occurred in the Late Eocene, Montanari et al. (1993) undertook a systematic search for Ir in 5 cm spaced samples from the Massignano section, near Ancona, which was at the time the best exposure of the Eocene-Oligocene transition known in the U - M region. A prominent Ir anomaly was found in a level dated at 35.7 + 0.4 Ma, and an other peak in a sample higher in the section. This encouraged further high-resolution impact stratigraphic investigations of this section, the exciting results of which are reported below.
258
5.8.3 The Global Stratotype Section and Point for the E/O Boundary at Massignano With a meeting of the IUGS Subcommission on Paleogene Stratigraphy at Monte Crnero (Ancona, October 1-3, 1987), a long period of prolific interdisciplinary stratigraphic research began in the abandoned quarry of Massignano, carried out by a number of international research teams. The quarry is located along the provincial road of the Monte Crnero Park, about 4 km north of the resort town of Sirolo (Fig. 5.7.6.14), fight at the terminal of the Ancona-Massignano city bus line No. 93. The quarry face exposes a 23 m thick, continuous, and complete sequence of pelagic marly limestones and calcareous marls, rich in well-preserved benthic and planktonic microfossils, spanning the upper Eocene and the lowermost Oligocene, and interbedded with several biotite-rich volcano-sedimentary layers. This was regarded as an ideal situation for the application of an integrated stratigraphic approach aimed at the precise and accurate calibration of the litho-, bio-, magneto, and chemostratstratigraphic records with direct radioisotopic datings. An IUGS Subcommission on Paleogene Stratigraphy special publication (Premoli Silva et al. 1988), containing several technical, interdisciplinary papers first discussed at the Monte Crnero meeting in 1987, was presented at the 28th International Geological Congress in Washington, along with formal proposals for promoting the Massignano quarry as the Global Stratotype Section and Point (GSSP) for the E/O boundary (Premoli Silva and Montanari 1989; Montanari and Odin 1989). The Massignano GSSP was formally established by the IUGS-SPS at the 1993 IGC in Kyoto (Premoli Silva and Jenkins 1993). A number of studies, further refining the mineralogic and lithostratigraphic (Mattias et al. 1992), biostratigraphic and paleontologic (Gonzalvo and Molina 1992; Molina et al. 1993), magneto-stratigraphic (Lowrie and Lanci 1994), chemostratigraphic (Montanari et al. 1993; Vonhof et al. 1998), and geochronologic (Odin and Montanari 1989; Oberli and Meier 1991; Odin et al. 1991) characteristics of this section were published independently in various international journals in the years after the Monte Crnero meeting. In particular, recent high-resolution stratigraphic studies lead to the discovery, at 5.6 m in the GSSP section, of an impactoclastic layer, possibly of worldwide occurrence, containing an iridium anomaly (Montanari et al. 1993), shocked quartz (Ctymer et al. 1996; Langenhorst 1996), extraterrestrial Ni-rich spinel and altered microkrystites (Pierrard et al. 1998), and a prominent anomaly of 3He (Farley et al. 1998), which was interpreted by Farley and co-workers as evidence of a comet shower that lasted some 2.5 million years. These new discoveries encouraged further detailed studies on the paleontologic and paleobiologic records of the Massignano GSSP aimed at the verification of the effects that the inferred cosmic events (impacts and comet shower) may have had on the terminal Eocene marine biota (Brinkhuis and Coccioni 1995; Vonhof et al. 1995, 1998; Gardin et al. 1999).
259
In 1993, A. Montanari commissioned a 40 m deep, continuous core, the socalled MASSICORE, which was drilled in the immediate vicinity of the GSSP (Montanari et al. 1994), coveting the stratigraphic interval of the exposed section, as well as some additional 15 m of the lower Oligocene. The MASSICORE is permanently stored at the Osservatorio Geologico di Coldigioco and it is available, upon request, for sampling and cooperative research. A detailed magnetostratigraphic study of the MASSICORE was carried out by Lanci et al. (1996), and studies on the foraminiferal, nannofossil, dinocyst, and stable isotope records are currently in progress under the leadership of R. Coccioni of the University of Urbino. Finally, on May 9, 1997, the Cbnero Regional Park inaugurated the Massignano quarry as an accessible "didactic-scientific site". Eugene and Carolyn Shoemaker participated in the inaugural ceremony as guests of honor. The reclamation work of the GSSP included consolidation and cleaning of the quarry face, landscaping of the adjacent area, and the instalment of two geological signs, with color pictures and explanations, in Italian and English, accessible to the general public. A 1999 updated integrated stratigraphic model of the Massignano GSSP is shown in Fig. 5.8.3.1. In summary, the Massignano GSSP constitutes an excellent playground for investigating on the effects that extraterrestrial events had on the marine, pelagic environment. Studies with this focus are currently in progress and, therefore, there is no definitive picture of the biologic changes, turnovers, or extinctions through the terminal Eocene in this section. For sure, we can say that nothing as severe as the K/T catastrophe occurred at this time. The terminal Eocene has been always regarded has a time of significant, but not drastic, change, a decline spread through a span of several millions of years, and seen by many researchers as a sequence of accelerated, step-wise extinctions (e.g., Keller 1986). Therefore, in the next chapter of this book, we will concentrate on the description of the impact stratigraphy at Massignano, leaving the more complex, yet fundamentally important, paleobiologic aspects of the terminal Eocene events to the several researchers currently working on them.
•
eo
impactoclastic layer (g, 10,12 13)
[]
[]
uncertain [ reverse
i
80
marly limestone biotite-rich volcaniclas~c layer
i
normal
Polarity
i
%60
(2)
marl/calcareous marl •
Llthology
->3 .>2-->1-.~0-19-181716151413~2-" I110987654321 0-
ITHOSTRATIGRAPHY
i
P18
P15
P16
j first '1 last occurrence occuronce ~ GSSP marker
MIcrofoosHs
11T. pomeroli (5.00) . G. semiinvoluts (4 501
I ~ cun/a/ens/s (7.SO)
I C. lazzar# (10.00)
G. index (13.50) 1G./uterbachen (12.90
1 C. inflata (15.00)
-iHantkeninidae (19.00 . . . . 1 T cunialensis (18.60 T cGcoaensis P17
I'G." tapuriensis (21.00)
Zone
age Ma = 36.53 - (0.15 x m) ± 0.4
Conversion formula m/age (8,11 )
i
100
Main events
(3a)
Planktonic Foraminifera
.
~"
i= :d
BB5
Zone
(ac)
LlC°N. b'uempy/ 2.50) /"1 C. ~'uncanus 2,00 C. subhaidingetii (1.50) BB4 JC. p s e ~ n g e r i a n u s (0.00)
Lo 1 N. truempy/ (g.00)
increase of small Bo//vk~a
~ presence of Cyclammina
J C. ccokei (23.00)
Main events
Benthonic Foraminifeca
i1 o0-
xle
b)
BIOSTRATIGRAPHY (3)
I I. recutvus (3.00)
I C~ rel/cu/atum (7.20)
I C. Idng~ (9.95)
D, saipanensis I D. batbadiet~s (13.50,-
acme (21.50) E. obmta
Main events
,=
Zone
(3d)
Calcareous nannofossils
GLOBAL STRATOTYPE SECTION AND POINT FOR THE EOCENE-OLIGOCENE BOUNDARY: T H E G S S P OF MASSIGNANO (1)
)161
~ne
~)
261
(12) CHRONO* GEOSTRATIGRAPHY "~RONOLOGY
Era: Cenozoic Ma
(million yeats) ~.5 34,5
~ste~Penod: Tolllary-PaJeoger~e Series Epoch
Stage Age
o@ @
j-I! -!1-
i
i
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,-
z
m --
uJ
O B-
O
r, m
O UJ
O.
REFERENCES
(1) Premoli Silva and Jenkins 1993 (2) Maffias et aL 1992 (3) Coccioni et al. 1988 (3a) Blow 1969; Berggren etal. 1985 (31:))Berggren et al. 1995 (3e) Berggren and Miller 1989 (3(I) Martini 1971 (3e) Okada and Bukw 1980 (4) Bice and Montaneri 1988
(s) Lowrie and Lanci 1994 (6) Odin et a1.1988 (7) Montanari et al. 1991 (8) Vonhof et aL 1998 (9) Montanari et aL 1993 (10) Fadey et al, 1998 (11) Pierrerd et aL 1998 (12) Montanari et al. 1985; Odin et aL 1988; Odin et aL 1991 0 3 ) Clymer et al. 1996; Langenherst lg96
Fig. 5.8.3.1. Integrated stratigraphic model of the GSSP for the Eocene-Oligocene boundary at Massignano (this page and facing page).
262
5.8.4 Impact Signatures at Massignano Asaro and Montanari (1988) first attempted the search for Ir anomalies in the classic section of the Barbetti Quarry at Contessa, near Gubbio (the CB section in Fig. 5.5.1), where detailed biostratigraphic and magnetostratigraphic data were available at that time (Monaco et al. 1987; Bice and Montanari 1988). The stratigraphic interval comprising the concurrent P16 and CP15b zones was chosen for this search on the basis of the known stratigraphic location of Late Eocene h" anomalies and spherules in other basins throughout the world (in particular the North American tektite strewn field and the microkrystite layers; see Montanari 1990). Out of 20 pilot samples analyzed with the coincidence spectrometer at Lawrence Berkeley Laboratory, two showed Ir concentrations of about 0.07 + 0.004 ppb, slightly higher than concentrations of about 0.04 ppb found in the other samples. Testing these two "anomalies" further, or performing a more accurate search in this section, was by then impossible because the Barbetti Concrete Company expanded the quarry, and the original CB exposure was lost after the quarry front receded by more than 200 m. Also the CQ section, on the opposite side of the quarry pit (Fig. 5.8.4.1), was temporarily lost after it was covered by quarry rubbte. Thus, the high-resolution scanning for Ir anomalies through a collection of 5 cm spaced samples, and subsequently for other impact signatt~es, such as shocked quartz, microspherules, spinel, and 3He, moved to the emerging Massignano section. A summary of the results of these investigations is reported below. Iridium. Two prominent peaks of Ir of 0.19 -- 0.02 ppb, and 0.33 - 0.01 ppb, were found at meter levels 5.61 and 10.25, respectively, in the Massignano section by Montanari et al. (1993). The lower peak, located in the upper part of Chron 16n2, and in the lower part of foraminiferal Zone P16, mid-lower part of nannofossil Zone CP15b (see Fig. 5.8.3.1), covered a 25 cm interval and comprised 5 samples with Ir concentrations higher than 0.08 ppb. On the other hand, the peak at 10.25 m (mid C15n, mid P16, and upper CP15b) was defined by a single sample. In addition to these, the Ir profile at Massignano showed another minor peak of about 0.1 ppb, defined by two samples at around 6.2 m in the section. Ratios among other trace elements, including Fe, Cs, Sb, and Se, were used by Montanari and co-workers to distinguish the characteristic background chemical profile of these pelagic carbonates from the several biotite-rich volcanic ashes interbedded with them, and to test whether the three Ir anomalies had a volcanic rather than extraterrestrial origin. The result was that the Ir peaks were true anomalies, in the sense that they were not derived from volcanic material, nor were they produced by diagenetic processes and/or precipitation from sea water.
263
Fig. 5.8.4.1. a) Re-excavated lower part of the Contessa Quarry (CQ) section; b) Close-up of the quarry face outcrop containing the Late Eocene impactoclastic It, and shocked quartz-bearing layer discovered by Clymer (1996) right at the top of a red band (RB) interval.
264
However, the peak at 10.25 m, represented by a single sample, remained somewhat suspect. The unusually high abundances of Ir, Se, and Sb, and, possibly, Ag in this sample could have been the result of sulfide precipitation in the sediment, but there is not enough iridium in the ocean water to accommodate 0.3 ppb Ir, and the samples just above and below 10.25 m have a normal (i.e., not leached) background around 0.04 ppb Ir. Further samples, covering the interval between 5 and 6 m, were re-analyzed by F. Asaro in 1994, and once again in 1995 (Clymer 1996). In this last scan, one sample at exactly 5.6 m yielded about 0.4 ppb It, a factor of two higher than in previous analyses. In 1995, the Barbetti Co. quarry re-excavated the lower part of the CQ section at Contessa (Fig. 5.8.4.1). This allowed Clymer (1996) to collect a suite of samples through a 2 m thick stratigraphic interval in which, in a marly layer located at the top of a pink colored band, he found shocked quartz (see below). This level was correlated with the Ir peak at meter level 5.6 in the Massignano section on the basis of the color change and available magnetostratigraphic data. The INA analyses performed by F. Asaro at LBL (in Clymer 1996, unpublished dissertation) revealed, in a sample from this shocked-quartz level, a relatively high Ir concentration of 1.06 -+ 0.04 ppb, a factor of 3 to 5 higher than in any of the previous analyses at Massignano. Iridium was measured independently at Massignano by Pierrard et al. (1998) through the same stratigraphic interval analyzed already three times at LBL. A maximum concentration of 0.28 _+0.02 was detected at 5.6 m, thus confirming the results of Montanari et al. (1993) and Clymer (1996). No further analyses to confirm the relatively high concentration of 1 ppb Ir were ever performed, to our knowledge, in the Contessa CQ section, nor across meter level 10.25 at Massignano, where Montanari et al. (1993) found an anomalous concentration of 0.3 ppb Ir. Shocked Quartz. Shocked quartz was first reported by Clymer et al. (1995) in the Ir-rich layer at meter level 5.6 of the Massignano section, and in the correlative layer in the CQ section at Contessa (Clymer 1996). The marly limestones throughout the upper Eocene at Massignano, normally contain 2% of sand-size mineral grains, 80% of which are quartz. Only 4% of the quartz faction, typically in the size range between 50 and 150 gm, display shock features (Fig. 5.8.4.2), and of these -5% show one single set of planar deformational features (PDFs), 28% contain two, and 67% have three or more sets (Clymer et al. 1996). Other samples representing genuine pelagic carbonates and biotite-rich volcaniclastic layers were also investigated by Clymer and co-workers in this section, but no shocked quartz grains were found. An independent crystallographic study by Langenhorst (1996) on the Massignano shocked quartz, using the transmission electron microscope (TEM), confirmed the shock metamorphic origin of the PDFs, which, according to this author, formed at shock pressures between 10 and 25 GPa, in a non-porous, quartz-rich, near-surface rock. This last inference was derived by the fact that high-pressure silica phases, such as stishovite and coesite, which are known to form in predomi-
265
nantly porous impact target rocks (Grieve et al. 1996), are absent in the Massignano shocked quartz.
Fig. 5.8.4.2. Shocked quartz grains from the Late Eocene impactoclastic layer at 5.6 m in the Massignano section. Scale bar = 0.1 mm.
Ni-rich Spinel and Microspherules. After an Ir anomaly and shocked quartz were pinpointed at 5.6 m in the Massignano section, a systematic search for impact spinel and microspherules was undertaken by Pierrard et al. (1998) through the whole 23 m thick section, with particular attention for the interval across the Ir- and shocked quartz-bearing layer. At meter level 5.6 Pierrard and co-workers found up to 800 Ni-rich spinel microcrystals per milligram of bulk rock, and no spinel was found in any other level analyzed in this section. Spinel microcrystals have sizes in the range of 10 ~m, a common dendritic habit often characterized by crossed arms (Fig. 5.8.4.3a, b), and can be seen with a powerful magnifying lens on a hand sample looking like very fine pepper dusting sparse throughout the gray, marly biomicrite. While sampling, Pierrard and coworkers noticed that in the layer at 5.6 m there were also round, flattened objects, mostly of a black color, fewer with a green color, and with diameters in the range of 0.2-0.4 mm. They were scattered throughout a 3-5 cm interval, and in a few
266
instances, they were concentrated in Planolites burrows (Fig. 5.8.4.3c). After a closer microscopic examination, they turned out to be flattened microkrystites (Pierrard et al. 1998). These spherules, which eluded for years the many researchers who worked at the Massignano GSSP, are extremely delicate, flattened to disks with 1:20 axial ratios (Fig. 5.8.4.3d), and they cannot survive routine sediment washing procedures such as the ones micropaleontologists usually apply with sieves and cloths under running water to separate and clean microfossils. Nor they can possibly survive rougher washing and acid treatments, such as those normally used to concentrate quartz and other silicate grains. The black, strongly magnetic spherutes are made of clustered spinel microcrystals (Fig. 5.8.4.3e), whereas the green spherules are made of a smectitic clay which, in thin section, exhibits internal fibral structures very similar to those of the K-feldspar spheroids found in the K/T clay (Fig. 5.8.4.3f). Extraterrestrial ~He. A conspicuous increase in extraterrestrial 3He was first detected by Farley (1995) in the upper Eocene portion of the Giant Piston Core from the North Pacific. This anomaly was interpreted as a signature of increased influx of interplanetary dust particles (IDPs) during a span of a few million years which covered the critical time of multiple impacts. This helium isotope is extremely rare in terrestrial crustal rocks, but relatively abundant in IDPs. However, particles larger than a few tens of micrometers would heat up entering the Earth's atmosphere to the point of releasing their helium, which, being very light, would be lost into the outer space. Thus, 3He is supposedly derived from very small particles, and a significant increase through a long span of time in the order of millions of years is suggestive of a comet shower, which not only would increase the possibility of multiple impacts (Hut et al. 1987), but implies a significant increase in the accretion on Earth of interplanetary dust. Poor age control in the carbonate-free, abyssal clay of the North Pacific GPC precluded precise correlation with the known Late Eocene impact record. Therefore, to better constrain the timing of this Late Eocene 3He event, Farley et al. (1998) performed a high-resolution scanning of the isotope content through the Massignano GSSP and the MASSICORE as well. An abrupt increase of the ~He content was detected starting at meter level 2, and reached a maximum, with a concentration a factor of about 8 higher than background, at meter level 5.6, exactly at the impactoclastic layer containing the iridium anomaly, shocked quartz, and impact spinels. A second ~He peak a factor of six higher than background was detected by Farley and co-workers at meter level 10.3, corresponding to the second, still unconfirmed, Ir peak measured by Montanari et al. (1993). The broad 3He anomaly gradually decreased to background levels at 16 m.
267
Fig. 5.8.4.3. Ni-rich spinel and microkrystites from the upper Eocene impactoclastic layer at Massignano. The most common crystal habit of Ni-rich impact spinel is dendrite, which is typical of rapid growth under nonequilibrium conditions. This habit (a; SEM image) is obtained by quenching in air of meteoritic material heated above liquidus (>1560 °C). On the other hand, skeletal and octahedral (b; SEM image) habits indicate crystallization from melt heated below liquidus. Microkrystites are often found in Planolites burrows (c, close-up photograph). Most of them are black, but some are made of a green (smectitic) clay (see arrow). Strongly flattened black micro-krystites (d; SEM image) are made of clustered microcrystals of spinel (e; SEM image), whereas the altered, smectitic microkrystites show, in thin section (f; crossed polarizers), fibrous structures similar to the altered K-feldspar microkrystites found in the K/T boundary.
268
In summary, the Late Eocene 3He anomaly, which covers a span of about 2.2 million years, from about 36.4 Ma to about 34.2 Ma, was interpreted by Farley et al. (1988) as strong evidence for a comet shower during which multiple impacts may have occurred. At present, we know of some four to five craters with ages covering this span of time (see Fig. 5.1.1 and Table 1.9.1). Two of these, the Popigai and the Chesapeake Bay impact structures, have diameters in the range of 100 km and fairly precise ages consistent with that of the impactoclastic layer of Massignano. The other impact structures, the Mistastin (28 km; 38 _+4 Ma), the Logoisk (17 km; 40 _+5 Ma), and the Wanapitei (7.5 km; 37 -+ 2 Ma) craters, are much smaller, and they would not have produced impactoclastic signatures recognizable in distant sections throughout the world. However, these smaller impacts may be part of the comet shower proposed by Farley and co-workers. A prolonged time of extraterrestrial bombardment, associated with a significant influx of interplanetary dust particles, could have been a main causal factor for the terminal Eocene global environmental changes and biological crises.
5.8.5 High-resolution Impact stratigraphy at Massignano The Late Eocene record in the U - M constitutes today an ideal situation for investigating the possible cause-and-effect relationship between extraterrestrial events and bio-environmental changes. The stratigraphic evidence for extraterrestrial accretion in the Massignano and Contessa sections, and the overall knowledge of the impact record (craters and impactoclastic layers in coeval sediments throughout the world) undoubtedly indicate that the Late Eocene witnessed a prolonged time of crisis, perhaps a comet shower, such as the one predicted by Hut et al. (1987) and seemingly confirmed by the 3He record revealed by Farley et al. (1998). However, no giant impact crater the size of the Chicxulub is known with a Late Eocene age, and no boundary layer like the K/T can be pinpointed and correlated with a sharp mass extinction. The possible cause-and-effect relationship between impact and bioenvironmental changes has to be searched through a stratigraphic interval several meters thick. However, the discrete impactoclastic layer at meter level 5.6 in the Massignano type section is good evidence that invites a closer look at what may be the sedimentologic and biologic response to a "non-lethal" impact event. In terms of physical stratigraphy, this impactoclastic layer is located at the very top of a pinkish band, which, in the Scaglia Variegata Formation of the U - M Apennine, can be considered as a precise and consistent regional lithostratigraphic marker (Fig. 5.8.5.1; see also outcrop images in Figs. 5.8.4.1 and 5.8.5.2). This interval is contained in the upper part of magnetic Chron 16n, although several magnetostratigraphic studies by different researchers in the CQ section at Contessa (Lowrie et al. 1982), the Massignano section (Bice and Montanari 1988; Lowrie and Lanci 1993), and through the MASSICORE (Lowrie et al. 1996), have yielded slightly different results (see Fig. 5.8.5.1). This is probably due to interla-
269
boratory differences in demagnetization and analytical techniques, and ways of interpreting paleomagnetic data. As for biostratigraphy, the impactoclastic layer is located in the upper part of planktonic foraminiferal P. semiinvoluta Zone (i.e., lower PI6 Zone), and in the middle-lower part of nannofossil zones NP19/20 and CP15b. Therefore, it is not located at a biozonal boundary, across which a faunal or floral change could be readily recognized with a magnifying lens directly on hand samples (as for the K/T) or even by looking at thin sections and smear slides with a standard microscope. As for the numerical age of this event, it is important to note that these marine U - M sections are, to our knowledge, the only ones in the world that have been calibrated with direct radioisotopic dating of volcaniclastic material (biotite, zircon, and monazite) interbedded with pelagic carbonates (e.g., Montanari et al. 1988b; Odin et al. 1991). An interpolated age of 35.7 _+0.4 Ma for the impactoclastic layer is derived from all the radioisotopic dating performed in a few of these biotite-rich volcaniclastic layers at Contessa and Massignano. Additional radioisotopic dating may provide, in the future, a more precise and accurate age for this impact event. Nevertheless, an age of 35.7 + 0.4 Ma is indistinguishable, within analytical uncertainty, from the ages of the North American tektites and microtektites (Glass et al. 1986b; Obradovich et al. 1989), the inferred age for the Chesapeake Bay impact structure (Poag and Aubry 1995; Koeberl et al. 1996c), and the radioisotopic age of impact melt rocks from the Popigai crater (Bottomley et al. 1997) (see Fig. 5.8.5.1). There is no direct evidence that indicates whether or not the impactoclastic layer at Massignano is related to the Popigai or rather to the Chesapeake Bay impact events. However, the fact that iridium, in Caribbean and Gulf of Mexico sections, is found in the microkrystite layer and not in the closely spaced microtektite layer, and that the latter is attributed to the Chesapeake Bay impact, suggest that the Massignano Ir-rich impactoclastic layer may be related to Popigai. Moreover, the absence of high-pressure silica phases in the shocked quartz of Massignano, which, on the other hand, are present in the Chasepeake Bay-related microtektite layer of DSDP 612 (Bohor et al. 1988), lead Langenhorst (1996) to suggest that Massignano shocked quartz was derived from the non-porous, crystalline target rock of the Popigai crater (see also Sect. 3.3 for further discussion). In any case, standing in front of the Massignano section, and looking at the interval between meter marks 5 and 6 (Fig. 5.8.5.2a), one would hardly imagine that some 35.5 million years ago two enormous extraterrestrial objects the size of Mont Blanc collided with the Earth in remote localities 5-6,000 km from here, excavating craters with diameters in the range of 100 km (i.e., roughly the distance between Massignano and Gubbio), each liberating energies equivalent to some 10 million megatons of TNT. From a distance, the visitor can only see a faint change in the color of these marly limestones, from pink to gray.
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Getting closer to the outcrop, one can see a clear break in sedimentation at 5.8 m, which is marked by a softer, more clay-rich layer. This is a biotite-rich volcaniclastic bed resting on top of a 50 cm thick marly limestone with a faint pinkish color. The pinkish limestone looks fairly homogeneous except for a 10 cm thick, hardly noticeable grayish band at 5.6 m (Fig. 5.8.5.2b). This band is the impactoclastic layer. On hand samples, it is possible to notice scattered mineralized spherules. In some rare cases, these spherules are concentrated in Planolites and Zoophycos burrows (Fig. 5.8.4.3c). However, many of the trace fossils through the whole marly limestone layer at the top the pinkish interval, including the thin impactoclastic horizon, contain biotite flakes that were derived from the volcaniclastic layer at 5.8 m. This gives an idea of the degree of vertical mixing in these sediments caused by intense bioturbation activity. Worms and other detritus feeding organisms that were living at or above the biotite level at 5.8 m penetrated the subbottom sediment for as much as half a meter, passing through the impactoclastic layer. On the other hand, the few burrows that contain spherules were probably dug by organisms that witnessed the impact event: they were pasturing on the impactoclastic layer immediately after its deposition. A polished rock slab of the top pinkish marly limestone reveals that the color change from pink to gray occurs right at the base of the impactoclastic horizon (Fig. 5.8.5.3a). Moreover, the intricate network of fossil traces seems to be interrupted between 5.61 and 5.63 m (Fig. 5.8.5.3b) by a relatively undisturbed band of sediment. These observations suggest that there has been a very brief interruption or decrease in bioturbation activity during the deposition of the impactoclastic layer which coincided also with a brief episode of relative reduction of the sea floor sediment. Normal oxidizing conditions were restored at around 5.67 m, as it is indicated by a return to a pinkish color. The arrival on the sea floor of volcaniclastic material at 5.83 m marks the definitive end of these slightly oxidizing conditions, and from here up to 9.5 m these marly limestones exhibit a gray color. All in all, the situation around the impactoclastic layer of Massignano, characterized by a decrease of bioturbation activity during a short episode of relatively low-Eh conditions, is somewhat similar to the K/T boundary with the difference that in the latter these events are much more marked and severe (see Sect. 5.7.4). Given this, the question remains on whether there has been a significant response of the plankton and/or benthos to the distant impact(s) represented by the impactoclastic layer. Preliminary results from a high-resolution, quantitative analysis across the Massignano section, using a multivariate statistical approach on planktonic Foraminifera and calcareous nannofossils, indicate that during a time of general, gradual cooling, an environmental break took place right after the impactoclastic layer was deposited, leading to accelerated pulses of temperature drops, which may represent the relatively long-term effects of this and other terminal Eocene impact events (Gardin et al. 1999).
272
Fig. 5.8.5.2. a) Panoramic view of the Late Eocene interval at Massignano. The frame refers to the close-up picture in b), which covers the interval between 5 and 6 m. The impactoclastic layer is found at a faint color change, from pink below, to gray above, at 5.61 m. The soft, receding layer at 5.8 m is a biotite-rich volcaniclastite.
273
Fig. 5.8.5.3. a) Polished slab of the marly limestone layer containing the Late Eocene impactoclastic layer at Massignano (5.61 m); b) X-ray contact print of the same slab (courtesy of the medical staff of the Civil Hospital in Cingoli), showing the complex network of ichnofossil burrows, which are apparently less abundant in the interval containing the impactoclastic debris.
274
5.9 The U - M Miocene Record During the Miocene, as the U - M Apennine fold-and-thrust belt started to grow and migrate toward the East, the onset of flysch deposition in NW-SE elongated foredeep basins interrupted the quiet carbonate, deep-water sedimentation, which begun back in the Triassic (see Chap. 4). While siliciclastic turbidites were invading this deforming Adrian basin, pelagic and hemipelagic carbonate sediments continued to be deposited in the easternmost edge of it, outside the deep flysch foredeep. In these external areas, open sea, carbonate deposition continued undisturbed until the beginning of the Messinian. After the Messinian salinity crisis, which in the eastern U - M basin was characterized by the deposition of evaporitic sequences, syn-orogenic siliciclastic deposition took over even in the most external, far eastern areas. Therefore, a nearly continuous and complete, turbidite-free Miocene sequence is found along the cliffs of the Cbnero Riviera, south of Ancona (Figs. 5.9.1 and 5.9.2). The integrated stratigraphy of this sequence, from the Langhian up to the Messinian, including calcareous plankton biostratigraphy, O, C, and Sr isotope stratigraphy, and radioisotopic dating of a few interbedded volcanic ashes, was studied in detail by Montanari et al. (1997a). Other turbidite-free, radioisotopically dated sections covering the rest of the Middle and Lower Miocene were studied in the hinterland of the U - M region, and were documented in detail by Montanari et al. (1997b and c), Coccioni et al. (1997), and Deino et al. (1977). In summary, in the Alpine-Himalayan orogenic domain, where the Miocene is usually represented by poorly dated, syn-orogenic and/or post-orogenic flysch and molasse deposits, the pelagic sequence of the U - M Apennine constitutes a rare, fortunate case. It represents that kind of ideal stratigraphic situation where a given geochronologic interval can be confidently and accurately localized in a discrete sequence of undisturbed layers (Fig. 5.9.3). In our specific case, the ejecta of a distant, well dated impact event can be searched in an interval a few meters thick. Unfortunately (for us) only a few, medium size craters are known at present in the Miocene impact record. One of these, Haughton in Canada, has a diameter of 24 km and a 4°Ar/39Ar age of 23.3 _+ 1.0 Ma. This age range corresponds, in our U M sequence, to a hiatus at the very top of the Scaglia Cinerea Formation, as it was inferred from detailed biostratigraphic analysis by Montanari et al. (1997b; see Fig. 5.9.3). No biotic crises show up in the Sepkoski (1996) diagram during this time, which coincides roughly with the Oligocene-Miocene boundary, and, in any case, the Houghton impact crater is too small and distant to deliver an impactoclastic signature to the U - M basin, even if this span of geologic time is here represented by continuous deposition.
275
Fig. 5.9.1. Location map of the stratigraphic sections exposed along the cliffs of Monte dei Corvi, near Ancona, which cover the interval from the mid Langhian to the lower Messinian.
On the other hand, the Ries crater in southwestern Germany, which also has a diameter of about 24 kin, is located only 600 km north of the Crnero Riviera, where a complete sequence of coeval marine, marly limestones are exposed in the La Vedova section (Montanari et al. 1997a). This 40 m thick section is located at the base of the Monte dei Corvi cliff and contains a volcaniclastic biotite-rich level, which, on the basis of calcareous plankton stratigraphy, was correlated with a similar volcaniclastic marker in the L'Annunziata section near Apiro (Montanari et al. 1997c). At L'Annunziata, this level yielded a preliminary laser fusion 4°Ar/39Ar age of about 15 Ma from single sanidine crystals (Montanari e t a l . 1988a), which is practically identical to the age of the Ries crater. Therefore, the La Vedova section may represent a promising area for investigating the regional effects that a medium size impact may have had on a proximal marine environment. To our knowledge, no studies focused on this interesting problem were undertaken to date in this section (although we have recently started an effort to remedy this situation).
Fig. 5.9.2. Panoramic view of the Monte dei Corvi cliffs and location of the sections studied by Montanari et al. (1997a).
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277
In addition to these two well dated medium size impact events, the Miocene record features two other small, distant, and poorly dated impact craters, Karla in Russia (12 km diameter; 10 _+ 10 Ma), and Bigach in Kazakhstan (7 km diameter; 6 _+3 Ma). However, these events are so inconspicuous that they could not have produced an impactoclastic signature in our U-M basin, nor they can be considered responsible for an environmental crisis recognizable at a global scale. Nevertheless, a small Ir anomaly was detected in coeval oceanic sediments in two distant sites (i.e., ODP 689B in the Weddell Sea, and ODP 588B in the Tasman Sea) by Asaro et al. (1988). This iridium signature, which in ODP 588B has a concentration of 0.15 + 0.01 ppb, was attributed by Asaro an co-workers to a large impact event, which would have occurred near the Middle-Late Miocene boundary, between 11.7 and 10 Ma. This stratigraphic interval corresponds also to a minor, actually the smallest extinction peak in Sepkoski's (1996) diagram. In the Monte dei Corvi section, the Middle-Late Miocene boundary, which corresponds to the Serravallian-Tortonian interstage boundary, has been precisely dated at 11.0 _+0.2 Ma (Odin et al. 1997). Once again, the U-M sedimentary sequence offers a remarkably complete, well exposed, and accurately dated stratigraphic section, where these events could be studied in great detail.
278
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6 Documentation and Laboratory Techniques
In this section we want to provide a very short overview of some of the simple field and sample preparation methods that are used to take and isolate samples for impact-related studies (including techniques that have been employed on samples described in Chap. 5), and review a few of the methods used in the study of shocked minerals and meteoritic components in impactites. It is beyond the scope of this treatment to cover standard petrographic and geochemical methods in any detail, or to discuss any paleontological and geophysical methods.
6.1 Documentation and Sampling in the Field The work of data acquisition in any geological research project starts in the field. However, in many cases laboratory analyses are performed by technicians or researchers who did not collect the samples personally, and may not be familiar with the field and the general geology of the collected samples. Therefore, correct sampiing and exhaustive documentation of the field work becomes as important as the precision and accuracy in routine laboratory analysis in the complex process of data production. Unlike an error in laboratory analysis, which can be (in theory) easily found and the analysis re-performed correctly, an error in the field documentation may not be as evident and, if found or suspected, it will require to go back on the outcrop, which may be difficult, expensive, or even impossible. Needless to say, an error in the field work is inevitably transferred into the lab leading to incorrect results and misleading interpretations. Whereas laboratory analyses are performed following precise routine procedures in a controlled and unchanging environment, field work (including outcrop observation and sample collection) may occur in such different environmental conditions (i.e., topography, weather, vegetation, etc.) and about so many different geological subjects (i.e., different rock types, outcrop exposure, accessibility, specific goals), that makes it difficult to establish a standard procedure of what to do and how to do things. Nevertheless, there are a few guidelines that can be taken as useful suggestions for correct documentation and sampling in the field. Once an outcrop is chosen as the place for investigating the possible presence of a meteoritic component and/or impact ejecta, either because it contains the paleontologic record of a biotic crisis or because it covers the time span of a major
280
impact event, the first thing to do is to locate it as accurately and precisely as possible on a map. If detailed topographic or geologic maps are not available, a standard road map can be used and coupled with a detailed description in the field note book of the location and appearance of the exposure. If available, a satellite global positioning (GPS) receiver can be used to obtain, directly in the field, the geographical coordinates of the locality. A sketch of the outcrop, with highlighting of reference items such as a tree or a prominent layer or a road sign, as well as a scale, is something always useful to do. Even better would be to take an instantaneous (i.e., Polaroid) picture of the outcrop to be pasted in the notebook. Highquality color pictures, digital or movie camera pictures, should be taken before, during, and after having finished the work on the outcrop. The next step would be to measure the section, and to gather information about the lithostratigraphy. As it often occurs in well-studied areas, such as the U - M Apennines, lithostratigraphic columns representing known sections are already available in literature, and some exposed sections may be provided with permanent markers (metal plaques or spikes driven into the rock, or signs painted on the outcrop). These signs, along with paleomagnetic drill holes, should be highlighted on the outcrop sketch or instant photo, and eventually in the log sheet. In those cases where permanent meter markers are present, a lithologic log should maintain the existing meter system. The best way of doing this is to use pre-made log sheets, in which lithologic information can be taken layer by layer. The information should be taken respecting a stratigraphic order on the log sheet, i.e., older layers below and younger above. If the section is not provided with permanent meter markers, then it is better to measure it before making a lithologic log. Measuring a section layer by layer while doing the log may introduce a cumulative thickness error. The lowermost exposed layer is usually taken as marker for the base of the section. However, it is always convenient not to call it "meter level 0" but rather "meter level 100.00". In this way, if later on an extension of the section is discovered stratigraphically below the one that is being measured, it may be numbered in continuity and with positive numbers. Before starting the acquisition of observations in the log sheet, the outcrop should be cleaned using a broom or a sturdy brush, and then marked every meter using a Jacob staff or a meter stick, trying the best to measure the actual stratigraphic thickness, that is the distance normal to bedding planes. In between meter marks, 10 cm subdivisions can be drawn on the outcrop with a permanent ink marker or a pencil. Of course, the distance between two meter markers on the surface of the outcrop is always greater than the real stratigraphic thickness, except in the unique case where the surface of the outcrop is perpendicular to the bedding plane, as well as the line between the two consecutive meter markers. So, in order to have accurate marking every 10 cm it is sufficient to divide by ten the actual distance on the outcrop face between two meter markers. The essential lithologic characteristics to be reported on the log sheet are the rock type (limestone, marl, clay, chert, sandstone, etc.), the rock color, the type of contact between consecutive layers (i.e., gradational vs. sharp), the presence and
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relative abundance of macrofossils (including trace fossils), and general notes regarding the state of preservation of the rock (weathering, tectonization), and the presence of sedimentary structures (soft-sediment slumping, lamination). Faults should be reported specifying whether or not the offset can be measured. The log sheet should also report the date, the name of the locality, and the name(s) of the operator(s). The section can be designated with an abbreviated code representing the name of the locality, and the year. For instance, a section logged in the Contessa valley in 1999 can be abbreviated with a code like CON/99. This code, followed by a meter level, will unequivocally designate a sample, which can be recognized immediately at any time in the future. In short, a sample coded CON/99113.52 indicates that it was collected in 1999 at Contessa at 13.52 m above the base of the measured section. Once the log is completed, sampling can proceed quickly and accurately. For relatively hard rocks such as limestone, hammer and chisel are the needed tools. Gloves and goggles are recommended for protection. Parts of the rock samples showing alteration or contamination should be chiselled out, and only the inner, fresh part collected. Sample size and spacing depend on which kind of analysis will have to be performed, and on the stratigraphic resolution one wants to obtain. Packing is best done in sturdy plastic bags. Zip lock-type bags, such as the ones used for preserving frozen foods, are the most popular and serve the purpose perfectly. The sample code should be written with a permanent ink marker both on the hand rock sample and on the plastic bag label. If the sample is larger than a few centimeters, a tick with the exact meter level, and an arrow indicating the stratigraphic up direction, should be written directly on it. For systematic and efficient sampling of limestones destined for geochemical analyses, which require very small amounts of material (i.e., stable isotopes, trace element analyses, etc.), we have often and successfully used a power drill with a standard 8 or 10 mm masonry drill bit. The best tool we used so far is a cordless 18 volt hammer drill, but a standard electric drill with a generator and a long extension cord has been successfully used in easily accessible sections (i.e., road cuts, quarry faces). This sampling technique requires also a small plastic funnel, and brushes to clean funnel and drill bit after each sampling. By placing the funnel directly against the exposed limestone layer and holding a plastic bag or a vial under it with one hand, a hole can be drilled fight above it into the limestone. The fine limestone powder produced by the hole drilling will fall into the funnel and directly into the sample bag. The sampling operation will take just a few seconds per sample. -A 2 cm deep hole with a 10 mm drill bit would produce about 4 grams of powdered sample. Beside the rapidity of the sampling, this simple technique produces already powdered, clean samples that will cut down tedious and long hours of preparation in the lab usually involving crushing and grounding whole rock samples with mortar and pestle. More care has to be taken in collecting soft rock samples, such as marl or clay. These rocks tend to be easily contaminated either by surficial outcrop contaminants (soil, plant roots, particles from industrial or engine pollution, debris from overlying layers; see Montanari 1986), or by the actual sampling procedure. The
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soft layer should be excavated some 5 to l0 cm before being collected, and only the larger, clean pieces taken. For thin clay layer sandwiched between hard limestones, like in the case of the K/T boundary, the best way is to remove the overlying limestone layer using hammer and chisel (or even a crowbar), and then collecting the clay with a spatula. Whole slabs of the clay layer can be preserved by wrapping them in aluminium foil, and carefully packing them into a plastic bag, which help preserve moisture and prevent crumbling. The clay layer preserved in this way can be carefully unwrapped in the lab and taken apart with tweezers for high-resolution (millimetric) study and sampling. Plastic tools are recommended in order to prevent any possible contamination of soft samples, especially for PGEs, although standard tool steel (hammer, chisel, spatula, tweezers, masonry drill bits) has been proven safe from contamination. On the other hand, jewellery such as gold or platinum rings may be a source for PGEs contamination (see Alvarez 1997, p. 67, note 4), and they should be removed while handling the samples in the field and in the lab as well.
6.2 Sample Preparation 6.2.1 Bulk Samples We only consider the necessary steps for preparing samples for standard techniques and those that involve platinum group elements. As a general rule, the less sample preparation is required, the better. Each preparation and treatment step increases the chance of contamination or loss. In geochemical analyses one has to always enter a compromise between available sample mass and what constitutes a representative sample. In the study of impactoclastic layers, this problem is even more severe, because of the low abundance of the impact-derived debris within a large amount of local matrix. It is necessary to consider if the goal of the analyses is to search for an extraterrestrial component in the first place, or to study in detail a known impactoclastic layer. In the first case, a large number of samples need to be scanned for impact-characteristic signatures, whereas the second case usually requires breaking down a large sample from a known location into its components. If proximal ejecta, or crater rocks, are studied, care has to be taken to obtain a representative set of target rock and impactite lithologies for chemical analyses and search for shock effects. In some cases, the characteristics of rocks from a particular crater structure are to be compared with the corresponding characteristics of distal ejecta to determine if there is a connection between the two. Taking all these considerations into account leads to a variety of sample preparation requirements, but they all have some points in common. The most important requirement is to avoid contamination. The search for siderophile element anomalies commonly involves very low elemental abundances, and cross-contamination
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from other samples, from crushers and mills, and during chemical treatment, can introduce severe problems that may not occur during standard geochemical work. In general it is advantageous to avoid using steel jaw crushers and any mills involving metal parts (e.g., those that use tungsten carbide or similar components and alloys, which are very common in standard swing mills). Coarse crushing can be done with the samples wrapped in thick sheets of plastic foil, followed by crushing in jaw crushers with ceramic jaws (e.g., alumina). Powdering of the samples to the required particle size for mineral separation (sieving) or bulk analysis is best done in alumina ceramic, agate, or boron carbide mills (of various designs). Boron carbide is brittle and very expensive, but it is useful for very hard materials, and our own experience has shown that it seems to be the mill material with the least amount of abrasion, which, therefore, leads to the least amount of sample contamination. Nevertheless, it is always a good idea to run blanks for each crusher and mill (using, e.g., pure quartzite), and to insert a cleaning step in between each sample (for example, by grinding clean, commercially available, sea sand). No equipment (for example, in central sample processing facilities) that has been used in the preparation of mineralized samples should be employed for the crushing and grinding of impact-derived material, as it is very easy to introduce contamination at the <109 g/g (sub-ppb) levels of interest here.
6.2.2 Isolation of Grains and Inclusions Sand-size grains of shocked quartz and impact spherules (microtektites and microkrystites) are the distal impactoclastic components recognizable with a lowmagnification optical microscope. Following the experience gained from working on the K/T boundary and the Late Eocene impactoclastic horizons in the U - M Apennines, we give herein a brief account of simple laboratory techniques that can be used to concentrate and isolate shocked quartz grains and microspherules from the types of sedimentary rocks encountered in this region (i.e., limestone, marl, and clay). We note that some of the procedures mentioned below involve dangerous acids and substances, and no responsibility can be taken for improper use of these substances. Following these procedures is entirely at the risk of the reader. Whereas spherules can sometimes be seen in a hand sample with a hand lens, shock quartz and other impact-metamorphosed mineral grains are usually very scarce and of small size in distal ejecta, and they require concentration from relatively large bulk rock samples (i.e., 100 to 1000 g) in order to be seen and studied with a petrographic microscope. If the sample to be investigated is a limestone or an indurated marl (like the Late Eocene impactoclastic layer at Massignano), it has to be crushed first with mortar and pestle down to a grain size of few millimeters to 1 cm. A solution of concentrated hydrochloric acid can be used to dissolve the carbonate into a large plastic bucket. Half a liter of cheap, industrial HC1 (the kind that is available in hardware or drug stores for domestic purposes) is more than sufficient to digest entirely a 100 g carbonate sample. The reaction of HC1 with the carbonate is fairly violent and it is best done outdoors or in a fume hood.
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Safety glasses should be used. Frequent stirring helps the reaction and the carbonate fraction of the sample can be dissolved in less than an hour. The muddy insoluble residue left in the bucket is first rinsed with abundant tap water three or four times, decanting the clay and silt that remain in suspension, and allowing sand grains (i.e., >63 ~tm) do settle down. The rest of the residue has to be wet sieved under running water in order to eliminate all the remaining silt and clay. This is best done with a polyester cloth with 63 ~tm openings. The cloth is placed into a plastic funnel into which the wet residue is pored. The cloth is then folded and twist wrapped around the residue like a candy bar and, holding it tight with one hand, it is brush-washed under running tap water using the other hand (the same way one would wash a pair of dirty socks) until all the silt and clay is rinsed out of the mesh. The >63 I.tm washed residue left in the cloth is then rinsed out into a ceramic bowl or a sturdy plastic can, and dried at low temperature (i.e., less than 100 °C) under a heat lamp or in an oven. Rinsing the wet residue with alcohol or acetone speeds up the drying. At this point, further concentration of quartz would require a Franz isomagnetic separator. If this machine is not available, then quartz grains will have to be searched among many other grains of silicate minerals, fragments of arenaceous benthic foraminifera, and pieces of radiolarian skeletons or other HCl-insoluble particles, such as fragments of impact spherules. Knowing that in distal impactoclastic layers, such as those of the K/T boundary and Late Eocene in the U - M Apennines, shocked quartz grains have an average size of around 100 ~tm, the residue can be dry-sieved with stacked 80 and 150 ~tm sieves. Quartz grains are recognizable under a reflecting binocular microscope, but they may be confused with clear sanidine crystals or other clear feldspars. They can be hand picked individually using a moist, very fine paint brush, and placed in a cardboard tray of the kind used for collecting microfossils. Later on, the grains are picked individually with the pin of a U-stage, and observed under a petrographic microscope to assess whether or not they contain planar features (see Sect. 6.3.5). A quicker way to check a sample for possible shocked quartz is to smear a small amount of sieved residue in transparent immersion oil onto a glass slide (the kind used for thin sections). Cheap Vaseline oil or clove oil would serve the purpose perfectly. Clove oil has the advantage over Vaseline of giving immersed sanidine grains a pale yellow tinge, and to quartz a light blue tinge, thus making them immediately recognizable with plain, transmitted light. Uncovered oil smear slides allow for moving the grains with a fine pin-point, and even to separate and recover them for further spindle- or U-stage study. Permanent and covered smear slides can be made using UV cement, the kind that hardens in a few seconds under ultraviolet light and is commonly used in car body shops to repair small cracks or holes in windshields. UV cement is routinely used by micropaleontologists for preparing nannofossil smear slides. The insoluble residue can be prepared also for a standard thin section using a simple grain mount technique. The residue is incorporated into fluid epoxy (the kind used for standard thin sections) and smeared over a support made of a cut block of marble or micritic limestone. Ready-to-use two component epoxy in
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small quantifies is today available at low cost in any hardware store, and serves perfectly our purpose. The block with the smeared epoxy residue mixture is then placed under a low temperature heat lamp for a quick curing. When hardened, the top surface of the grain mount is polished over spinning metal laps using water and carborundum grits in decreasing grades (from 320 to a polish finish of 1000 grade), until cut sections of the mounted grains are exposed on the surface of the polished grain mount. Alternatively, grinding and polishing can be performed with a paste of grit and water over thick glass plates, or even, without the grit paste, over wet polishing sand paper of the kind used in car body shops. Finally, the polished mount surface is glued over a thin section glass slide using UV cement or epoxy, sliced with a diamond saw, and then ground down to a standard 30 g m thickness petrographic thin section. If the purpose is to separate particles other than resistant quartz grains, such as altered microkrystites or delicate microfossils, the wet sieving procedure described above has to be performed very gently, especially when washing the residue in the polyester cloth under running water. A long immersion of ground marlstone in hydrogen peroxide would produce a certain amount of loose mud without damaging carbonate and other more or less delicate grains. In this case, also calcareous microfossils and fish teeth will be preserved, and can be concentrated after gentle washing with the polyester cloth or a standard sieve. Marls and marly limestones (up to 75 wt.% CaCO3) can be disaggregated using the following technique. A sample made of small chunks of rock (the size of walnuts) is heated to a temperature of about 300-400 °C (a cast iron frying pan over a kitchen stove or a Bunsen burner would do just fine). The hot samples are then thrown into a bucket filled with kerosene (i.e., diesel fuel) using a pair of long tongs (safety glasses should be worn). The hot sample will first sizzle for a second and then it will cool down quickly (best is to do this operation outdoors and in an open space). Once the sample is soaked with kerosene, it is transferred into a bucket of hot water, and in a short time it will disaggregate to a loose mud. Calcareous and silicate particles can then be wet sieved or washed using a polyester cloth as described above. For clay-rich samples, such as the K/T boundary clay, grinding with mortar and pestle, digestion in HC1, or soaking in kerosene is not necessary. The clay can be disaggregated quickly and gently in a beaker of water or even better in a 30 vol.% solution of hydrogen peroxide. If laboratory grade H202 is not available, standard 10-15 vol.% hydrogen peroxide of the kind sold in a pharmacy for medical use is good enough to help break down the clay sample. In the case of the K/T clay, the wet-sieving procedure using a polyester cloth has to be performed very gently in order to prevent fragile particles, such as altered impact spherules made of glaucony, to break down. Cleansing in an ultrasonic bath is not advised because glaucony spheroids, as well as some arenaceous benthic foraminifera, would disintegrate. Spherules and microfossils can be hand-picked using a moist, very fine paint brush under a reflected-light binocular microscope as described above. An aliquot of the bulk washed residue can be digested in HC1, which will produce an insoluble residue containing impact spherules, silicate grains (including shocked
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quartz), and arenaceous benthic foraminifera. The various particles of these residues can then be treated as described above for making grain-mount thin sections or smear slides, or prepared for SEM or TEM study. The spinel-bearing and smectite spherules in the Late Eocene impactoclastic layer are very fragile and extremely flattened, and cannot be separated from the enclosing hardened calcareous marl using the wet-sieving, polyester cloth washing, H202 disaggregation, or HCl-dissolution techniques described above; they would disintegrate inevitably. The best way to separate and isolate them is to pluck them with a needle or the edge of a razor blade (or a cutter) directly from a raw hand sample under a reflected-light binocular microscope. For making thin petrographic sections of these spherules, a small, dry slice of the soft marly limestone should first be impregnated with fluid epoxy in a vacuum, and then polished. In absence of a impregnation vacuum set-up, a thin coat of fluid epoxy, or even an impregnation with fluid used for masonry coating on the surface of the sample exhibiting such flattened spherules may be sufficient to keep them together while gently polishing them on a glass slab smeared with fine grit paste, or on a sand paper sheet of the kind used for metal polishing. If the sample to be cut or polished contains water soluble components, it is better to use oil for lubrication rather than water.
6.3 Laboratory Techniques It is beyond the scope of this book to discuss all techniques that have been, or can be, used in the recognition and study of impact-derived rocks and distal ejecta. However, we felt that it was appropriate to give at least brief summaries of some of the more important methods for the determination of a meteoritic component and the identification of shocked quartz, as these determinations are of crucial importance to confirm an impact origin of the investigated rocks.
6.3.1 Standard Bulk and Microprobe Analysis Methods After the preparation of bulk samples for analysis, almost any method for major, trace, and isotopic analysis available to modem geochemistry can be used. This type of analysis will be most often used on rocks taken directly from a (suspected) impact structure, such as suevites, impact melt rocks, and target rocks (for comparison). The first step, which is unrelated to actual analytical methods, though, is to study any rock that should be chemically analyzed by standard petrographic methods, i.e., by doing a classical thin section description with the petrographic microscope in transmitted light. This study is necessary to define the rock type(s) and to determine if, and how much, melt clasts (or matrix) there might be present, and/or to study the clast population in a target rock or breccia, which is necessary for interpreting chemical data (for an example, see French and Nielsen 1990).
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Bulk analyses are usually of little importance for the study of the components in impactoclastic layers, as in these cases we are only looking for a few grains (of, e.g., quartz or spinel) in a foreign matrix, but they can also be important for the search of siderophile elements (e.g., Ir) in a stratigraphic profile. Once the rocks to be studied have been prepared for analysis (usually as powders; see Sect. 6.2.1), a variety of methods for major and trace element analysis can be employed. The most common ones are X-ray fluorescence (XRF) spectrometry (with sample powder pressed as pills, or with glass disks made by fusion of sample powder and a flux material), inductively coupled plasma atomic emission spectrometry (ICP-AES), inductively coupled plasma mass spectrometry (ICP-MS), and instrumental neutron activation analysis (INAA). All of these methods allow the simultaneous (rarely sequential) determination of a large number of major and trace elements. Requirements for sample mass vary somewhat, depending on the method (XRF tends to need several grams of material, whereas a few tens to hundreds of mg are sufficient for the latter three methods). An introduction to the basics of these techniques can be found in, e.g., Gill (1997), and more details on the methodology are provided in the excellent textbook of Potts (1995). Neutron activation analysis has the advantage that sample preparation is minimal: sample chips or fragments (or whole grains or spherules, such as microtektites) can be used as they are, or powdered samples are analyzed without any pressing, melting, or dissolution (each of which could introduce contamination). Small sample sizes can cause problems if samples are not homogeneous (which they rarely are). Analysis of single grains or fragments are representative of this one particular component of a mixture (which may be desired), but not of the mixture as a whole. Samples analyzed by INAA can, after completion of the counting procedures, be mounted for other analyses, such as electron microscopy, electron microprobe, or ion microprobe. Details on the use of INAA for small sample analysis are given by Koeberl (1993c). Electron microbeam techniques (e.g., scanning electron microscopy [SEMI in combination with energy dispersive X-ray [EDX] analysis, or electron probe microanalysis [EPMA]) are used to determine the mineral composition of a mixed sample, usually from a petrographic thin section that has previously been studied by optical microscopy), or the properties of single grains or spherules. Regarding the study of single mineral grains and spherules of possible impact origin, it cannot be emphasized enough that simple (SEM) photographs, or even semiquantitative EDX spectra of such samples, have no diagnostic meaning whatsoever. Unfortunately the literature (especially the unrefereed literature, such as abstracts) is full with claims of "new types" of spherules or grains, all of which have supposedly formed by some impact process or are derived from some (always "new" or "usual") extraterrestrial source, with all these claims based on the interpretation of photographs and/or crude surface analyses. Detailed studies of such claims have revealed a host of "down-to-earth" explanations (e.g., Montanari 1986; Byerly et al. 1990), ranging from industrial contamination, natural concretions, opaque minerals, remnants of abrasion or erosion,
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or even insect eggs. Most of these mis-identifications could have been avoided if proper analytical procedures had taken precedent over enthusiasm or wishful thinking. After surface photography (where desired), all such samples have to be mounted, sectioned, and polished for mineral phase identification and quantitative analyses. Surface analyses may be useless and meaningless. Once sectioned, mineral grains and spherules reveal their internal smacture (mineral assemblages, zonation, etc.) and can be analyzed by EDX or EPMA methods (note that in some cases the resolution of EDX systems is not good enough, and before very unusual compositions are reported it is prudent to check them with more sophisticated equipment, such as wavelength-dispersive EPMA). Back-scattered electron (BSE) images, taken with an SEM instrument, are also very useful for such investigations. The misidentification of meteor ablation spherules, which are common on Earth in a variety of sedimentary environments, as impact-derived spherules can easily be avoided by detailed analyses (BSE images of sectioned samples and EDX analyses), as most ablation spherules have a characteristic composition (often dominated by olivine and magnetite, but they may also be glassy or metallic in composition; see, e.g., Blanchard et al. 1980; Brownlee 1981). With any analytical method, two points are of specific importance: a) the method used in a study must be properly documented and referenced, and b) international standard reference materials must be used for quality control. Details that should be reported for any analytical procedure used are given in Table 6.3.1.1.
Table 6.3.1.1. Information required for proper documentation of analytical techniques. • • • • • • • • • • •
Samplepreparation procedure (give details of the types of mills) Originalsample quantity Samplemass used in analysis Instrumentation(equipment used) Analytical conditions (for example, in EPMA: acceleration voltage, sample current, beam diameter, counting time) Data reduction methods Type of standards Precision (reproducibility) of method Accuracy of method Detection limit
When reporting analytical data (e.g., in a table or a figure), some items require attention. First, units have to be indicated for all results (taking into account that "percent" alone can be ambiguous, as there are wt.%, atom.%, vol.%, etc.). Second, it is important to print only a realistic number of significant digits. To give all data to two decimal places (simply because of the convenience of spreadsheet output) is annoying and betrays a precision of the data that is not supported by the analytical method. For example, to report a chromium content of, say,
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751.58 ppm, when the method has a precision of 3 rel.% (i.e., about 23 ppm!), is misleading and clutters the data table with useless numbers. To report EPMA data of, for example, 0.0212 wt.% MnO, when the detection limit of the method is on the order of 0.01 to 0.02 wt.%, is equally unrealistic. A final note refers to the unsettling practice of reporting "zero" values in data tables (which is another artefact of the uncritical use of spreadsheets or direct instrument output). Zero values do not exist in nature and cannot be measured; there is always one atom or another of a certain element in a finite sample mass. Thus, such values should be reported either as "below detection limit" (in such cases it would be desirable that the actual detection limit is reported in the table, as a "less or equal than" value) or a note should be made that this element was "not analyzed" in this particular sample. All these comments refer to good geochemical analytical practice, but should especially be observed when dealing with the low abundances (of, e.g., the siderophile elements) in impact-derived rocks.
6.3.2 Iridium Determinations The determination of the PGE iridium is the most commonly used scanning technique in the search for chemical impact markers. This element gained notoriety especially in the early days of the K/T boundary dispute (see Sects. 1.1, 1.8, and 3.2). Although this point has been made before, it should be emphasized that the reason that often only the Ir content is measured is because this element can be determined with greater sensitivity and more ease than any of the other PGEs. Thus, Ir acts as a marker for the other PGEs, which, if an Ir anomaly is found, may then also be determined in a limited subset of samples (given the much greater analytical efforts for complete PGE analyses). There is a variety of techniques for measuring Ir contents, with the most commonly used ones based on neutron activation. The reason is the very high neutron capture cross section of the isotope 191Ir, resulting in the radioactive 192Irisotope, which decays (half life: 74.2 days) by combined 13-7 decay, with several gammalines in the region of the gamma-spectrum in which detectors are most sensitive (e.g., major lines at 296, 308, 316, and 468 keV). Detection limits of routine INAA procedures vary according to the neutron flux during irradiation, duration of irradiation, counting duration, detector sensitivity, and sample composition (the latter influencing the background of the spectrum), but are commonly on the order of 0.5 to 2 ppb lr (see, e.g., Koeberl 1993a, c). Radiochemical methods (e.g., Palme et al. 1978, 1979; French et al. 1989) can be used to measure lower abundances, but are tedious. Detection limits can be significantly improved by using 77 coincidence spectrometry, as described by, e.g., Meyer (1987), Rocchia et al. (1990), and Koeberl and Huber (2000). The technique makes use of the coincident decay of 192Irby counting a radioactive sample simultaneously with two detectors and plotting the resulting three-dimensional coincidence spectrum (Fig. 6.3.2.1).
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70 60 5O 40 cts 30 20
~
1
266.1
~
266.1
316.5 368.7 418.0 468.1
31;.5 ~ 3687
keV Detector 2
418
468.1
keV Detector 1
Fig. 6.3.2.1. Partof a gamma-gammamultiparametercoincidencespectrum,showingthe spectral regionfrom about260 to 500 keV, with the coincidencepeaks at 316 x 468 and 468 x 316 keV. In such a spectrum, the coincidence space is represented by a plane and only signals that are recorded within a short coincidence window (usually a few hundred nanoseconds) appear as peaks that grow out of the plane. In the case of '92Ir, the two most intense lines are at 316 and 468 keV, and each of the photons emitted (at 180 ° of each other) in the coincident decay can cause a coincidence signal in both detectors, resulting in prominent peaks at 316 (detector 1) x 468 (detector 2) and 468 (detector 1) x 316 (detector 2) keV. The volume of the peaks is a measure of the intensity. This method drastically reduces the background that limits detection in a single spectrum. Alvarez et al. (1980) employed a similar technique, but with additional background reduction using a large guard detector, resulting in relatively short measuring times. The coincidence method allows the analysis of a fair number of samples with detection limits that are on the order of 5 to 30 ppt (10 .'2 g/g or pg/g) Ir, again depending on the irradiation, instrumentation, counting, and sample parameters (e.g., Rocchia et al. 1990; Huber et al. 1999, 2000; Koeberl and Huber 2000). Recently, ICP-MS techniques have been used for Ir analyses, but require larger samples, chemical sample preparation (dissolution, separation), and reach the detection limits obtained by coincidence counting only with great analytical effort.
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Isotope dilution techniques (with the measurements made by thermal ionization mass spectrometry or ICP-MS) are very precise and yield very low detection limits, but the great experimental effort makes them impractical to use for reconnaissance purposes. Also, after completion of the counting for INAA the samples can be re-used for other analyses.
6.3.3 Platinum Group Element Determinations Most methods for PGE analysis used in geochemistry have been developed for the study of, or reconnaissance for, commercially important ore deposits; more recently, some methods were developed for the study of mantle rocks. The abundance levels of interest in impactite studies are several orders of magnitude lower than those in ore deposit studies. Chondritic meteorites have average abundances of (for example) about 700 ppb Ir, 1800 ppb Pt, 700 ppb Pd, and 900 ppb Ru (see Anders and Grevesse [1989] for cosmic abundance values). Typical mantle xenoliths have abundances on the order of 2 ppb Ir, 5 ppb Pt, 2 ppb Pd, and 4 ppb Ru. The upper continental crust, into which impacts of meteoritic projectiles occur, has abundances that are about a factor of 100 below those of mantle rocks. As discussed in Chap. 1.8, impactites contain very small meteoritic contributions (usually"well below 1 wt.%). Assuming (for example) that 0.2% by weight of a chondritic projectile (the most common meteorite type) is mixed in with upper crustal rocks yields (for Ir) 700 x 0.002 = 1.4 ppb in the resulting impactite (and we note, as mentioned in the previous section, that Ir is the easiest of the PGEs to determine). Abundances in impactoclastic layers are commonly much lower (see discussion in Chap. 5). Quantitative PGE determinations at sub-ppb abundance levels are analytically very challenging. Earlier studies (e.g., Morgan et al. 1975, 1979; Morgan 1978; Palme et al. 1978, 1979, 1981; Wolf 1980) used radiochemical methods, where the PGEs were separated from the sample matrix, and in some cases from each other, after neutron irradiation (i.e., radiochemical neutron activation analysis, RNAA). This procedure involved (for example) dissolution of the radioactive sample by alkali fusion or acid digestion, followed by ion exchange, liquid extraction, and/or precipitation steps that may be repeated several times for better separation efficiency. Counting and data reduction were then done by standard INAA techniques. Such procedures are not much used anymore due to the reluctance of handling radioactive samples in liquid form, and because of the radioactive decay of short-lived isotopes during the time-consuming separation steps, which lead to a loss of signal. More recently, the development of reliable ICP-MS instruments, both with quadrupole and high-resolution MS, has provided the geochemist with another tool for low level PGE work. The sample digestion and separation procedures are still similar to those used before in RNAA work. One of the most common methods involves a Ni sulfide fire assay with Te co-precipitation, followed by ICP-MS measurements. A typical recipe can be summarized as follows (Koeberl et al.
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2000a, modified after Jackson et al. 1990): thoroughly mix 6 g of Na-carbonate, 12 g borax, 0.7 g sulfur, 2.10 g Ni carbonate, and 3.5 g of silica with 10 g of sample powder; transfer into a fire clay (or porcelain) crucible; fire for 90 minutes at 1060°C; remove, let cool, and break open the crucibles; separate the Ni sulphide buttons, break, and transfer fragments to a 500 ml beaker containing 120 ml of concentrated HC1; dissolve on a hotplate; co-precipitate PGEs from solution with Te using SnC12 as a reductant; filter insoluble noble metal-bearing residue through a 0.45 gm nitrocellulose filter paper and wash; place filters inside a 100 ml screwtop Teflon vial; add 4.0 ml of concentrated HC1 and 3 ml of concentrated HNO3; seal and place overnight at 40°C in a waterbath; cool (ice), open, and dilute with water to 100 g; spike solutions with internal standard monitors for instrumental drift; measure on ICP-MS instrument. Detection limits obtained with this method by Koeberl et al. (2000a) are (in ppb) 0.02 Ir, 0.05 Ru, 0.02 Rh, 0.14 Pt, 0.10 Pd, and 0.02 Au. A somewhat similar procedure was recently developed by Hassler et al. (1999), which allows not only the determination of the PGEs, but also of the Os isotopic ratio in the same sample (see next section). Their method uses PGE isotope spikes, which are introduced at the dissolution step, providing the advantages of isotope dilution methods (e.g., elimination of yield determination). Several problems with all these methods result from sample size and detection limits. First, due their low abundances the PGEs are often inhomogeneously distributed in rocks, which, together with sensitivity limits of the measurements, require a large enough sample for a representative analysis. This causes problems with complete dissolution of such large samples, and, because of the larger amount of chemicals required in the following steps, leads directly to the second problem: potentially interfering blank levels of the PGEs in the reagents used. For example, great care has to be employed to obtain NiS that has low enough levels of the PGEs so that blank values do not interfere with sample values. Procedural blank values of standard NiS/Te-coprecipitation methods can reach 0.1 ppb. Reduction in sample weight to 5 g and digestion of the sample powder in a modified Carius tube (Shirey and Walker 1995; see also next section) led to improved procedural blanks of (for example) <3 pg/g for Ir and <6 pg/g for Ru and Pd (Rehkarnper et al. 1998). However, all such determinations are at the current limits of analytical geochemistry and require a dedicated laboratory and great analytical experience. No PGE measurements at the sub-ppb level are routine.
6.3.4 Osmium Isotope Measurements The basics of the method are discussed in Sect. 1.8.3. In principle, it is necessary to determine the ratio of the radiogenic Os isotope, '87Os, compared to a nonradiogenic Os isotope. Osmium has seven naturally occurring isotopes, which are all stable. The isotopes and their abundances (in parentheses; given in rel.%) are: 18408 (0.024), ~S6Os (1.600), ~87Os (1.510), ~88Os (13.286), 18908 (16.252), ~9°Os (26.369), and ~92Os(40.958) (Faure 1986).
293
The amount of 187Osincreases with time as a result of the decay of lSTRe. This decay can be described by normalizing to an Os isotope not affected by radioactive decay: ~87Osf188Os= (~8~Os/~8Os)~+ (~TRef188Os)(e~ - 1) where ~87OsflSSOs and ~Re/~8~Os are the measured ratios of these isotopes, (~8~Os/~8~Os)~is the initial isotopic ratio at the time when the system became closed for Re and Os, )~ is the decay constant for ~87Re (ln2/tl~2, with t~j2 being the halflife), and t is the time elapsed since system closure for Re and Os. Normalization to ~88Os is preferred over 186Os (which was used earlier, e.g., Allbgre and Luck 1980; Luck and Turekian 1983), because '~Os also has a (rare) radiogenic source, and because '88Os has higher abundances and is the isotope actually measured by most workers. With this equation it is possible to calculate an "age" if the initial isotopic ratio of Os is known. Alternatively, it is possible to calculate the initial Os isotopic ratio from a suite of samples with the same age, in analogy to the Rb-Sr method (Faure 1986; Shirey 1991). The use of this isotope system to determine an isochron requires a very high precision of the analytical measurements. In the 1980s, the available techniques did not allow such precise (or sensitive) measurements. The situation changed in the early 1990s with the development of the negative thermal ionization mass spectrometry (NTIMS) technique for Os isotope measurements (V61kening et al. 1991; Creaser et al. 1991). This method allows the determination of abundances and isotopic ratios of Os and Re at the low abundance levels found in most terrestrial rocks. However, two crucial points are the complete dissolution of the samples and the equilibration of the sample with the isotope spike. The addition of a spike of known isotopic composition is necessary to determine the concentration of Os (and Re) by isotope dilution (Faure 1986; Potts 1995). There is a variety of methods for the determination of the Os content and isotopic composition, depending on the goals of the analyses. For example, it is possible to determine only the l~7OsflS8Osratio, or the isotope ratio plus the Os content, or both plus the Re content. There are only two naturally occurring Re isotopes, 187Re and ~85Re, and 187Reis used (normalized to ~88Os)in a standard Os isotope diagram (see Fig. 1.8.3.1). It should be noted, though, that these diagrams were designed for isochron work, where samples of the same age fall on a straight line. In impact studies, this diagram is used in a different way. Here, different components (e.g., several different target rocks and impact melt rocks or breccias) plot in widely dispersed locations in the Re-Os diagram. Target rocks commonly have high ~87OsflSSOsand 187RefSSOs ratios, whereas meteorites plot in a specific location in the lower left of the diagram, at very low values for these ratios. The target rock and meteorite values define the endmembers in a mixing relation, with impact breccias and melt rocks commonly plotting in between the endmember values (if all endmember compositions were analyzed). This type of application places different constraints on the analytical precision compared to mantle geochemistry (e.g., isochron work; cf. Shirey 1991). In the latter case, differences in
294
the isotopic ratios by fractions of a percent can have important implications, whereas in impact studies differences more likely are in the order-of-magnitude range (e.g., meteorites have a 187Os/188Osratio around 1, whereas ratios for target rocks can vary between 5 and 100; cf. Esser and Turekian 1993; Koeberl and Shirey 1997). It may not be necessary to determine the Re content, as the Os content and isotopic ratio alone yield the desired answer. Most modem analyses involve a high temperature acid digestion step for dissolution of the rocks and isotope equilibration between the spike and the sample Re and Os, followed by separation of the Os in some sort of distillation, and isolation of Re by anion exchange chromatography. However, it has usually been difficult to obtain complete digestion of mineral constituents and isotope equilibration between spike and sample Re and Os. Only recently have these problems been solved by the application of the so-called Carius tube digestion method, which involves sealing sample powder with mixed concentrated acids into a thick walled quartz or borosilicate glass tube (Shirey and Walker 1995). It is clearly important that the samples do not come into contact with metal and are ground in a contamination-free mill (e.g., agate or alumina). The low abundances of Os in terrestrial samples require the use of fairly large samples, about 2-10 g of sample powder. Samples are spiked with enriched '9°Os and ~85Re (Shirey and Walker 1995). For the NTIMS measurements, Re and Os fractions are loaded (separately) on filaments (commonly Pt) that have to be cleaned to remove any Re background, and are measured as negative ReO 4- and OsO 3- ions, respectively. Measurements can also be done by ICP-MS (see previous section). After correction for oxygen isotopic composition and fractionation, and normalization of the Os isotopic ratios (192Os/~88Os= 3.0826), abundances of Os and Re, and the '87Os/'8~Os ratio, can be calculated. A different method was recently described by Hassler et al. (1999). These authors isolate the PGEs in more or less the same way as for "standard " ICP-MS analyses (see previous section), by adding a multi PGE isotopic spike and then using a Ni-sulfide fire assay preconcentration procedure. However, after dissolution of the metal beads in a Teflon container, volatile OsO 4 is purged (with Ar) directly in an ICP-MS instrument (without a nebulizer), allowing direct, rapid (measurement time is a few minutes), and very sensitive measurement of Os abundance and isotopic composition. The remaining solution can then be used for "normal" ICP-MS measurement of the abundances of the PGEs. This method has several advantages over the standard NTIMS Os isotope measurements by being much faster and very sensitive, and also allowing the determination of the PGE abundances in the same sample. A disadvantage is that the analytical precision is not as good as in NTIMS analyses, which is, however, of little concern in impact studies. The rapid technical progress in this field will likely allow even more sensitive and faster analyses in the near future.
295
6.3.5 Methods for Shocked Quartz Measurements As described in Sect. 1.6.4, planar microdeformations in rock forming minerals are probably the features that are most characteristic of shock pressures related to an impact event and, thus, provide diagnostic evidence for an impact origin. The mineral most commonly studied for shock features is quartz (e.g., St6ffier and Langenhorst 1994; Martinez and Agrinier 1998), because it is abundant in many crustal rocks, is stable over long periods of geological time, is an optically simple (uniaxial) mineral, and displays a wide range of planar features whose development is correlated with shock pressure. Other rock forming minerals also show microdeformations, but either they are difficult to quantitatively measure, such as in feldspar (because it is a biaxial mineral), or the minerals are relatively rare in crustal rocks, as with olivine (see, e.g., Kieffer et al. 1976b; Bischoff and StOffier 1992). It should be noted that, under some conditions, shocked minerals can weather faster than their unshocked equivalents (Boslough and Cygan 1988; Boslough 1991). The characteristic appearance of planar microdeformations in quartz, such as PDFs (see Sect. 1.6.4), is evident under the optical and electron microscope and can reveal, to the experienced worker, confirming evidence of an impact origin. Care has to be taken, however, in the proper identification of PDFs, and possible confusion with tectonic deformation lamellae (B6hm lamellae) has to be excluded (see Sect. 1.6.4 for criteria). Basically, tectonic lamellae are relatively thick, widely spaced, and curved bands, whereas PDFs are narrow, closely and regularly spaced, straight features that extend though the whole quartz grain and often occur in more than one set. PDFs can be studied either in thin sections of rocks or in single grains isolated from a matrix. Besides (qualitative) identification of these features in the petrographic microscope, it is possible to use the electron microscope to distinguish between tectonic features and PDFs. Gratz et al. (1996) described a method in which quartz grains are etched and then studied in the SEM. Etching procedures include the following options: a) rinsing of grains for a few minutes in a 30 vol.% HF solution (followed by neutralization of the samples, e.g., with Na2CO3, to avoid etching of microscope parts by HF vapor); b) HF vapor etching of a thin section or grain mount (e.g., on top of an open HF bottle); or c) hot alkaline solutions (e.g., 0.0010.01 M KOH at about 200°C for 4 hours in a sealed Teflon container). As PDFs are filled with amorphous quartz, they are preferentially etched and appear as narrow and straight lines with so-called internal "pillaring", which is visible at high magnifications (Gratz et al. 1996). Tectonic deformation lamellae are either not etched or show broad arrays of curvy dislocation loops. However, once PDFs are indicated by optical or SEM work, more definitive (quantitative) work should follow. Ideally, this would involve a combination of optical and transmission electron microscope (TEM) studies, but the tedious sample preparation techniques and expensive and specialized instrumentation for TEM work precludes the wider use of this method (for examples, see MUller 1969;
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Kieffer etal. 1976a; Gratz etal. 1988, 1992a; Goltrant etal. 1991; Leroux etal. 1994; Cordier and Gratz 1995). Optical (and related) parameters for the investigating shock metamorphic effects in quartz include the following: a) decrease of refractive index, density, and birefringence with increasing shock pressure (measurements to determine refractive indices, using the spindle stage, are described by Bloss [1981] and Medenbach [1985]); b) mosaicism (either by optical measurements [e.g., Dachille et al. 1968] or X-ray diffraction [e.g., H6rz and Quaide 1971]); c) infrared and Raman spectroscopy (e.g., Velde and Boyer 1985); and d) NMR and related structural methods (e.g., Cygan et al. 1990; Boslough et al. 1995). For details on these parameters, see Chap. 1.6 and the excellent reviews by St6ffler and Langenhorst (1994) and Langenhorst and Deutsch (1998). Cathodoluminescence analyses may be of potential interest (e.g., Owen and Anders 1988; Seyedolali et al. 1997), but not enough data are presently available. For reasons of space and simplicity, we discuss only one very important method here: the measurement of the crystallographic orientations of PDFs using a universal stage. The goal of these measurements is to measure the angle between the c-axis and the pole of the plane of the PDFs, as well as the azimuthal angle, in a quartz grain. A stereographic projection of the rational crystallographic planes in m-quartz (Fig. 6.3.5.1) illustrates this point. The c-axis is at the center of the projection, and the outer limit of the diagram marks a polar angle of 90 °. The azimuthal angle is measured between the three a-axes (al, a2, a3); for example, the {1013} (or co) plane has an azimuthal angle of 30 °, whereas the {1121} (or s) plane has an azimuthal angle of 60 ° . The measurements can be done using a so-called universal stage (U-stage). These microscope attachments came into use in the early decades of the 20th century for petrofabric work and for compositional measurements on plagioclase. Two different types exist: one with four, and one with five axes. The four-axis model (e.g., Reinhard 1931) consists of an inner vertical axis I-V, an outer vertical axis O-V, and two horizontal axes [the inner north-south (N-S) and the outer east-west (O-E-W) axis], whose point of intersection lies in I V . The order of the axes from the inside out is: l-V, N-S, O-V, and O - E - W (followed by the vertical microscope stage). All axes have graduated circles that allow the precise reading of the amount of rotation. The sample is placed on a glass plate at the center of the stage, with glass hemispheres of known refractive index (for quartz: 1.554) above and below the glass plate. The fifth axis in the five-axis stage (e.g., Emmons 1943) is useful for the measurement of biaxial minerals; it is not needed if uniaxial minerals (such as quartz) are measured. Fig. 6.3.5.2 shows a four-axis U-stage.
297
r
(lOlO)
Fig. 6.3.5.1. Standard stereographic projection (lower hemisphere) of rational crystallographic planes in o~-quartz, which is used to index crystallographic planes of PDFs based on universalstage measurements. The arrows indicate the three a-axes of quartz, and the c-axis (the (0001) plane) is in the center of the projection. Also indicated are the low Miller indices in a part of the diagram (other indices can be derived from crystal symmetry). The circles are about 5 ° in diameter and indicate the accuracy of the U-stage measurements (see, e.g., Engelhardt and Bertsch 1969; diagram after Koeberl 1997a).
298
Fig. 6.3.5.2. Four-axis universal stage (Leitz), showing the glass hemispheres at the center (which contain the sample thin section), followed by the four axes; from inside out: inner vertical, inner horizontal (N-S), outer vertical, and outer horizontal (O-E-W). The latter is operated by the large knob on the right side of the U-stage.
A detailed lab manual of the operation of a universal stage is beyond the scope of this treatment. However, in short, the measurement of PDF orientations involves the following steps: a) set-up of U-stage (place special objectives into microscope and center; place thin section into stage and assemble stage; place Ustage on microscope stage and fix with screws; center U-stage; adjust height of plate); b ) m e a s u r e orientation of quartz c-axis (set all horizontal axes to zero; rotate grain on I - V to extinction; test orientation by rotating on N - S ; rotate O - E W by 15-30 ° - grain should leave extinction; rotate on N - S to extinction; rotate on O - E - W back to zero and note readings on I - V and N - S ) ; and c) measure orientations of PDFs (reset axes to zero; rotate I - V until set of PDFs is parallel to crosshairs, then rotate N - S until planes appear as sharp and narrow as possible; note readings on axes). The measurements have then to be plotted using a standard
299
stereonet (Wulff net), assuming the lower hemisphere of the stereoplot. In principle, the optical axis (c-axis) is rotated into the center of projection and the locations of the poles of PDFs are plotted; this is practically done either by a computer program, or manually with a transparent overlay on the stereonet and the angle between the c-axis point and the pole point is measured once the two are rotated so both are on a N-S great circle (meridian). This angle can then be compared to the rational crystallographic planes in quartz (as shown in Fig. 6.3.5.1). The precision of such measurements has been estimated from practical work at about _+4° (B.M. French, personal communication, 1994). For practical plotting purposes, the "bin" size, with which the angles are plotted in a histogram, with the measured angle on the x-axis, should be about 4 to 6 °. The measured angles that fall within 5 ° of the theoretical polar angle of the plane are considered valid and can be indexed. Unequivocal assignment of the specific Miller indices is impossible if only one plane per grain is observed, as some of the crystallographic planes occur (as a result of the symmetry class of a-quartz) in positive and negative or fight and left forms with three symmetrically equivalent planes. A distinction is only possible if at least one plane of each form is present. If the unequivocal assignment of planes to Miller indices is not possible, general forms are identified as the low index planes and written in curly (or wavy) brackets. Only the basal orientation (0001) can be determined unequivocally (Carter 1965). In a histogram, only the polar angle information is plotted (on the x-axis). There is a variety of histogram types, depending on how the data are plotted on the x-axis and what is plotted on the y-axis. Different workers have used somewhat different diagrams in the past. Some workers plot all data, giving "number of observations" (i.e., number of measured planar microstructures) on the y-axis. Others present frequency in percent on the y-axis, again using all data (i.e., absolute frequency). Others again plot frequency in percent, using only the total number of indexed planes for normalization. Definitions are given by Engelhardt and Bertsch (1969) and StOffler and Langenhorst (1996). In most cases, plots are presented as bar diagrams, with the width of the bars equivalent to the bin size mentioned above (compare Fig. 1.6.4.3). More recently, Grieve and Therriault (1995) and Grieve et al. (1996) proposed to use fence diagrams, in which all observations within the error of the measurement are assigned to the corresponding crystallographic orientation and plotted as a single line with a height corresponding to the relative frequency (i.e., without plotting unindexed planes or the variation in measurement). Fig. 6.3.5.3 shows the results of this procedure. It is obvious from the literature that different workers have different plotting preferences, but no matter which method is used, the details on how a specific diagram was constructed (i.e., how indexing was done and what type of frequency is plotted) must be given. Two or more PDF planes per grain allow, in principle, specific indexing. Results from this procedure can be shown in single grain, multiple plane stereoplots, which are useful only if three or more sets of PDFs are found per grain.
3OO
Newporte Crater 24 planes (18 grains total) 33.3 % unindexed planes
(.0
--: 25 v
co U_
a 20 [1. --(3
r,z
7r
(9
x 15 --(3 c
C
o 10 >, o
S
c.-
7 O"
5
LL 0
I
I
I
I
I
I
I
I
I
10
20
30
40
50
60
70
80
90
Angle Normal to Pole of c-Axis (Degrees) Fig. 6.3.5.3. Crystallographic orientation of PDFs in quartz from the Newporte (North Dakota) impact structure, shown as a histogram giving the frequency of indexed PDFs versus angle between c-axis and poles of PDFs, without plotting unindexed planes (see Grieve and Therriault 1995 and Grieve et al. 1996); the shock-characteristic orientations (000l), {1013}, {1012}, {1122}, {1011}, {0111}, and {1121} (c, co, n, ~, r, z, and s, respectively), are dominating (diagram after Koeberl and Reimold 1995a).
In summary, the study of shocked quartz is not as simple and straightforward as showing a photograph of a quartz grain with some kind of (sub?)planar features. If optical microscopy shows the clear and unambiguous presence of multiple sets of straight, closely spaced planar features, there is a good chance that these represent PDFs. SEM studies of etched samples might amplify such a conclusion. Confirmation, and shock barometry studies, however, require the determination of crystallographic orientations by using U-stage and optical microscopy work, or by TEM investigations, which also allows verification that the planes are filled with an amorphous phase. The study of PDFs in other minerals follows equivalent procedures, but can be more complicated depending on the crystal structure of the minerals, and be impeded by the fact that much less is known about the development and shock pressure dependence of microstructures in these minerals compared to quartz.
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Index
Y-7 coincidence spectrometry 289 ~°Be 80, 91, 92, 93 ~87Os/188Os 49, 50, 107, 118, 293, 294 Os/ Os isotopic ratios 49 29R magnetochron 103, 219 3He 62, 109, 131,189, 195, 219, 231,253, 258,262, 266, 268 4°Ar/39Ar 51, 122, 123, 171, 194, 195, 255-257, 274, 275 A. mayaroensis 200 Aalenian 174 Abatomphalus mayaroensis Zone 200 ablation spherules 64, 65, 74, 113,288 Abruzzo 157, 164, 165 accretion 62, 153,189, 195, 198,254, 266, 268 accretionary lapilli 146 accuracy 167, 171,288 achondrites 44 acid rain 127, 217 acoustic fluidization 21 Acqualagna 204, 228 Adelaide 138 Adria 157, 162 Adriatic Promontory 157 aerodynamically shaped tektites 64 Africa 11, 86, 157 age paradox 90 Agost 106, 253 airblast 12, 61 Alamo Breccia, Nevada 148, 149 Albian 163, 164 Albion Island, Belize 126, 128 alkali feldspar 83, 133 allochthonous 25, 39 Alpine-Himalayan orogenesis 57 - orogenic domain 274 Alps 165 amino acids 108 Ammodiscus 210, 248 I88
-
187
-
-
.
Anabar Shield 133 Ancona 131,164, 203, 256-258,274, 275 anhydrite 125, 162 anoxia 203 anoxic event 164, 174, 189 Antarctica 82, 131,150, 251,254 apatite 52, 96, 224 Apennines 158, 162, 165, 172, 173, 185, 186, 190, 197, 200, 201,203, 206, 239, 247,250, 256, 278,280, 283, 284 apographitic diamonds 35 Apollo 8, 153 Appalachian 79, 83 Aptian163, 164 - Albian (A/A) 168 Ar-Ar technique 52, 68 Archean 64, 72, 73, 79, 80, 133, 142-144, 148 - spherule layers 142 Arctic Russia 194 - Siberia 254 arenaceous benthic - foraminifera 284-286 - foraminiferal tests 207 - foraminifers 227 - benthonic foraminifers 244 Argentina 7, 46, 155 Arizona 5, 15, 34, 43 Arroyo el Mimbral, Mexico 123 Ashanti, Ghana 86 asteroid(s) 1, 3, 6, 14, 63, 153, 198, 209 impact 3, 14-16, 124, 142 Atlantic Ocean 86, 129, 152, 185, 208, 256, 257 Australasian strewn field(s) 59, 64, 66, 68, 70, 72-80, 84, 88-94 Australia 11, 13, 48, 53, 55, 65, 91, 93, 94, 139, 141,142, 146, 148, 150, 152, 153 -
-
-
352
australites 64, 65, 73, 74, 88, 91, 92, 94, 95 Austria 85, 150-152 authigenic 201,207, 220, 249
B. jacobyi 178 baddeleyite 36, 64, 78, 93, 96 Bahamas ! 57 Bajocian 163 ballen - structure 37 texture 38 Barbados 69, 81,255-257 Barberton 142-144, 148 Barbetti Quarry 262 Barremian-Aptian boundary 181 Barriasian-Valanginian 163 basaltic melt 207 base surge 39, 58, 126 Barringer, Daniel Moreau 5 Basque Country 192 Bath Cliff section, Barbados 257 bathysiphon 211 Bauma interval 231 Bay of Bengal 91 Bedias, Texas 80 bediasites 74 Belgium 148 Belize 126, 128 Beloc, Haiti 111,112, 123, 253 benthic - foraminifera 210, 284, 285 - foraminifers 172, 203, 210, 227, 236, 241,248 benthos 271 Berriasella jacobi 178 Berriasian 140 BerwindCanyon, Colorado 107, 110, 111 Besednice, Czech Republic 84 bioclasts 20t biogenic ~atcite 198 biologic turnovers 215 biomicritic limestone 164, 178 biosphere 7, t94 biotite 52, 60, 224, 253, 255, 256, 258, 262, 264, 269-272, 275 bioturbation, 200, 203, 204, 209-213, 215, 218, 222, 231,235, 237, 239, 244, 271 biref~ngence 23, 33,296 Birimian Supergroup 87 Bisciaro 166, 219 -
bituminous shales 184 bivalves 192 black shale(s) 159, 164, 174, 187 Blake Nose, Florida 107, 129 bleaching 203, 218 blind test 124 Bohemia, Czech Republic 85 B t h m lamellae 28, 295 bolide 15, 106, 108, 109, 112, 117, 141, 217 Bon Accord 145 Bonarelli - Level 164 - Oceanic Anoxic Event 184 boron isotopes 80 Bosso Gorge 178 BottaccioneGorge 180, 181, 185, 197, 198,223-225 bottle-green microtektite 76, 77, 93 bottom current 204, 210 Bouguer gravity anomaly 117 .bowl-shaped craters 7, 20 Brazil 28, 29, 55, 129 twin(s) 28, 29 breccias 24, 25, 36, 39, 40, 42-44, 46-48, 50, 52, 118, 120, 122, 134, 293 Brown Clay Member 181,182 Brownie Butte 109 Brunhes-Matuyama - boundary 75 - reversal 88 Bugarone Formation 163 Bunte Breccia 40 Bunyeroo Formation, Adelaide 138 Burano 186 - anhydrite 162 Burdigalian 166 Bushveld Complex 148 -
Cagli 178, 186, 201 calcarenitic turbidites 165, 201, 203, 211, 231,241,247 calcareous algae 241 - marl(s) 101,258, 286 - nannofossils 165, 178, 271 calcic feldspar 204, 220 calciruditic turbidites 239 calderas 3, 7 Caltisto 10, 156 Calpionella brevis 179 -
353
Cambodia 75, 89 Cambrian 134 Camerino 201 Campanian190, 191,194, 195, 201 - Maastrichtian boundary 194 Campeche platform 217 Canada 7, 26, 46, 54, 55, 82, 112, 117, 131,151, t53, 184, 274 Candigliano River 228 Caravaca 106, 108 - section 206 carbon isotope stratigraphy 108 carbonaceous chondrites 51 carbonate(s) 27, 146, 154, 157, 262, 264, 269 - apron 239 dissolution 198 - ooze 198, 200, 218 - platform(s) 157, 162, 164, 165, 192, 201,239, 247 - reefs 184 Caribbean 81,130, 207, 254-256, 269 Carius tube 292, 294 cataclasites 39 catastrophism 192 cathodoluminescence 155,296 CB section 262 Cenomanian-Turonian (C/T) boundary 155, 164, 168, 184, 247 cenotes 117, 119 Cenozoic 72, 133 Central Apennines 157, 164 European strewn field 68, 73, 80, 84, 85 Pacific Ocean 6t central - peak(s) 3, 8, 20, t32, 136 - uplift 7, 11, 13,20,26 Cetona Formation 162 chalcopyrite 142 charcoal 107, t08 chert(s) 164, 165, 178, 185, 247, 251,253, 280 China 66, 75, 80, 148, 150, 151 chondrite(s) 4 A 46, 48, 49, 51,118, 154 chromite 48, 64, 77, 142 chromium 288 isotope(s) 43, 107, 50 cinder cones 3 circum-Antarctic current 254 -
-
-
-
-
Clear Creek North, Colorado 102 clinopyroxene 81, 91, 130, 204, 207, 220, 256 coccoliths 218 Coccolitophorida 217, 218 coesite 24, 34, 64, 78, 130, 256, 264 collapse 1, 19, 21,150 Colombacci Formation 159 Colorado 102, 107, 110, 111,121,122 comet(s) 3, t4, 15, 63, 88, 109, 131, 142, t50, 156, 189, 195, 198, 253, 258, 266, 268 impact 3 - shower 156, 159 compaction 219 complex craters 7, 10, 11, 20 compression stage 16, 19, 58 concordia diagram 121 condensed sequence 163 cone-in-cone structure 26 Crnero Riviera 274, 275 conjugate faults 231 contact /compression stage 14 stage 19, 58 contamination 186, 196, 224, 227, 281283, 287,294 Contessa 281 - Highway section 180, 224, 225, 253 - Valley 180-182, 224, 250 continental - crust 74, 76, 79, 153, 157, 171, 220, 291 - drift 4,5 Coon Butte 5 copious carbonate production 236 corals 241 Corfino 172, 173 Crrniola Formation 163, 174 corundum 64, 78 cosmic spherules 62, 196 cosmogenic radionuclides 91 CQ section 262, 264, 268 Cr isotopic composition 43, 107, 51 Crater Mountain 5 crater chains 156 floor 5, 7, 9, 81 - rays 59, 60 - rim 7, 9, 13, 24, 39, 40, 57, 59, 94, 104, 118, 132 -
-
-
-
-
354
rocks 1, 52, 87, 88 fill 39 Cretaceous- 1, 3, 63, 102-104, 107, 109, 114, 120, 124, 125, 127, 129, 130, 132, 134, 137-140, 156, 159, 162, 163, 165, 166, 168, 177, 179-181, 190, 192, 197, 199, 200, 203, 204, 209, 210, 213-219, 222, 223, 229, 231,233-237, 239-241, 243-245 - T e r t i a r y (K/T) boundary (see K/T boundary) 1,140, 159 cristobalite 64 Crow Creek Member 137, 138, 152 crushers 283 crustal rocks 3, 17, 21, 38, 43, 44, 49, 64, 72, 79, 80, 98, 141,266, 291,295 crystallographic orientations 24, 29, 31, 32, 133 Cuba 80, 128 cyclicity 164, 185 Czech Republic 85
-
Danian 124, 190 Darwin glass 78 Deccan Traps 125 decompression 19, 47 deep-sea sediments 61, 75, 86, 88, 91 dendritic - crystals 207 - structures 204, 207, 208, 265 detection limit 49, 91, 132, 154, 288 devitrification 38, 52 Devonian-Carboniferous boundary 155 diagenesis 48, 207 diagenetic alteration 207 diamonds 35, 36, 61,108, 112, 136, 270 diaplectic glasses 23 Diaspri Formation 163, 178 Dicarinella 184 diffraction pattern 27 dikes 25, 39, 87 dissolution 36, 107, 204, 209, 218, 221, 223,237, 286, 287, 290-294 distalejecta 139, 48, 51, 52, 57, 59-61, 63, 69, 75, 94, 99, 101, 104, 113, 115, 122, 123, 132, 137-139, 141, 148, 149, 152, 155, 156, 167, 180, 282, 283,286 dolomite(s) 17, 134 Dorothia 211 Dresden, Germany 85 DSDP Site
216 130, 131 - 292 130, 131 - 462 136 - 465A 206 - 576 106 - 577 106 - 596 31,114 - 612 69, 78, 82, 131,257, 269 dumbbell-shaped 204 dysoxia 251 -
E/O boundary 250, 254-256, 258 Early Cretaceous 97, 166 - Eocene 164, 166, 251 Oligocene 254 Earth's orbit eccentricity cycles 212 earthquakes 6, 16, 237 echinoid 241 eclogites 21 EDX 287, 288 Egypt 95 ejecta 1, 19, 24, 39, 40, 51, 53, 57~51, 85, 92, 99, 101, 104, 112, 113, 122, 123, 126, 128, 129, 131, 133, 136, 138, 139, 141, 144, 146-149, 152, 154, 155, 180, 198,217,274 blanket 59 E1 Kef, Tunisia 101,124, 218 electron microprobe 287 Eltanin event 10 endogenic 109, 114, 151 - metamorphism 21, 22 Eocene- 61, 62, 82, 91, 131, 132, 136, 159, 165, 166, 189, 195, 201,204, 207, 208, 250, 251,253-259, 261,264, 266268, 270, 271 - Oligocene (E/O) boundary 166, 254 equation of state 17, 18 erosion 6, 7, 11, 13, 21, 25, 46, 48, 58, 117, 165, 171,224, 287 escape velocity 14 Ethiopia 174 eugubina - layer 215 limestone 198-200, 214, 215, 219, 221223,228, 229, 231,234-236, 241,244 Europe 11,150, 152, 157, 184, 189 Euxinic Shale 166 evaporites 159, 217 excavation 14, 19, 57, 58, 93 -
-
-
-
355
stage Exmore breccia -
14, 19 83, 132, 133
F/F boundary 148, 150 fallback ejecta 7, 9 feldspar(s) 1, 17, 24, 27, 30, 34, 52, 93, 109, 118, 133, 137, 204, 206, 207, 209, 284, 295 felsites 72 fibrous structures 204, 208,267 field documentation 279 Finland 54, 62 fireball 58, 59, 61,102, 103, 105, 113 fish tooth 236 fission track 46, 51, 52, 54, 94, 224, 255 flanged-button australites 64 Flaxbourne River, New Zealand 108 flexural slip folding 207, 224 flood basalts 125 Florida 129, 157 fluid inclusion 29 flute(s) 241 casts 241 flysch 159, 165, 166, 224, 239, 274 Fohn- 1, Timor Sea 131 fold-and-thrust belt 157, 159 Fonte d'Olio 209, 240, 244, 246 Foraminifera 124, 165, 217, 284-286 foraminiferal turbidites 237 Fornaci 204, 240, 241,244, 245 - East quarry 245 - Quarry C. section 204 - West quarry 245 fossil meteorite 106 Fossombrone 204 fractive index 23 fragmental impact breccia 40 Frasnian-Famennian (F/F) 148 Frontale 203, 209, 211,223, 231-236 - outcrop 209 fulgurites 36 fullerenes 61,108, 109, 150 Furlo 185-188, 201, 203, 204, 210-214, 217, 218,222, 223,236-239~ 244 - Gorge 237 Upper Road section 185-188, 212 Via Flaminia section 204
-
-
-
G. -
cerroazulensis
-
cretacea
256, 257 200, 219, 235
218 235 - minutula 235 - semiinvoluta 256, 257 Galilei, Galileo 3 Galileo 2, 3 Ganymede 10, 156 Garrnfo 247 gas hydrates 130 Gaspra 2 Gavellinellidae 209 Genga 204 Georgia 80 georgiaites 74 gersdorffite 142 Gessoso-Solfifera Formation 166 Giant Piston Core 253,266 Gifford, Algernon Charles 5 Gilbert, Grove Karl 4 glacial deposits 155 glass(es) 21,24,29,33-37,40,41,43,59, 64,68, 69,72,73,75-78,80-82, 86, 88, 89,91,97,111,112,118,120-123, 139, 155, 204, 207, 219, 253, 257, 284-287, 294,296,298 glaucony 204, 207, 209, 214, 215, 219222,224,239,244,249 Global S~atotype Section and Point (see GSSP) 101,159, 258 global wildfires 107, 108 Globige~na eugubina 197, 200 Globige~na~ka semiinvoluta 256 globigefinids 197, 223, 231,236, 239 Globorotalia cerroazulensis 256 Globotruncana 216 Globotruncanidae 197 Globotruncanita 216 goethi~ 203, 204, 207-209, 214, 215, 220, 222, 244, 248 Gorgo a Cerbara 204 goyazite 103 grabens 157, 162 gradualism 192, 255 grain flows 239 granite(s) 17, 32, 72, 87, 137 granodiorite 17 graphite 24, 35, 36 gravity 11, 19, 57, 58, 89, 116, 117, 132, 139,146 Gre~ Sand Sea, western Egypt 95 greenhouse 217 -
cretacica
-
fringa
356
Greenland 153, 154, 253 GSSP 102, 159, 218,258,259, 261,266 Gruithuisen, Franz von Paula 4 Guangxi, China 66 Guatemala 95, 129 Gubbio, Italy 159, 101, 166, 180, 181, 185, 190-192, 195, 197, 198, 200, 201, 203, 210, 212, 213, 216, 217, 219, 223, 225, 227, 228, 231,235, 237, 239, 244, 250, 251,262, 269 Gulf of Mexico 105, 130, 254-256, 269 Gumbelitria cretacea 200, 218 Hadean Earth Haiti 89, 111,112, 120-123, halogens 74, 89, Hamersley Basin, Western Australia heat flow heavy noble gases
153 129 127 146 16 90
Hedbergella - planispira
216
181 HEL 17, 18 Helmintoidea 211 Helvetoglobotruncana helvetica 185 hematite 106, 203,222, 224 hemipelagic 166, 274 Hercynian 162 Herschel, Friedrich Wilhem 3 Heterohelicidae 197 Hettangian Calcare Massiccio 162 Hevelius, Johannes 3 hiatus 198, 200, 215,274 high pressure phases 23 - polymorphs 24, 34 high-sanidine 206, 207 histogram 299, 300 HNa/K australites 74, 94, 95 Hoba iron meteorite 15 Hooke, Robert 3 horst 162 Hospital Hill, Witwatersrand Basin 33 Hugoniot - elastic limit 17 equation(s) 17, 18 Hutton, James 4 hydrofluoric acid 29 hydrothermal alteration 48 hypercanes 127 hypervelocity impact 14, 15, 64, 72, 80, 109 -
-
- crater
15
ichnofauna 211 ichnofossil 212, 273 ICP-AES 287 ICP-MS 154, 287, 290, 291,294 illite 206 Ilyinets 30 impact angle 4, 42, 45 - cloud 217 crater(s) 2, 3, 5, 7-1t, 13-16, 19-21, 24, 26, 34, 37-39, 43, 45, 50-53, 69, 85, 88, 94, 96, 123, 132, 141, 155, 162, 167, 171, 173, 250, 251,255, 268, 274; 277, 278 -Acraman, Australia 43, 53, 61, 138, 139, t46, 152, 154 - Ames 11 Mauritania 46, 47, 92, 93, 94 - Avak 11, 54 Bee Bluff, Texas 82 - Bigach, Kazakhstan 54, 277 Bosumtwi, Ghana 37, 41, 42, 46, 54, 61, 70, 79, 80, 86, 87, 152 - BP 96-99 Brent, Canada 47 Bay 11, 54, 62, 70, 7983, 131-133~ 136, 152, 168, 195, 268;g;lIlhicxulnb 6, 10, 11, 48, 53, 54, 61, 63, 101, 104, 108, 113-127, 141, 152, 168, 190, 195, 268 Darwin 78, 93 East Clearwater, Canada 46 - Gardnos, Norway 53 Gosses Bluff 13, 21, 55, 141,177 Haughton Dome (Devon Island, Canada) 26, 274, 278 - Henbury 46, 93 - Isidoms D 8 - Kalkkop, South Africa 50 Kamensk, Russia 54, t71,251,253 Kara, Russia 54, 115 Kara 171,190, 194, 195 Karla, Russia 277 - Logoisk, Russia 54, 55, 195, 268 Lonar, India 93 Manicouagan, Quebec 151, 168 -Manson 11, 54, 103, 115, 120, 121, 136-138; 152, 171,190, 194, 195 -
-
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A
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357
- Meteor Crater 5, 14, 34, 43, 46, 47 -Mistastin, Canada 54, 82. 131, 136, 195, 268 55, 141,168, 177 -Montagnais 54, 82, 251,253 Morokweng, 46, 51, 55, 139-141, 168, 177, 180 - Newporte 11, 25 Oasis 96, 97, 98, 99 Odessa, Texas 46 - Popigai 35, 54, 62, 82, 131, 133-136, 152, 168, 195, 254, 268-270 Red Wing Creek 11, 27 36, 40, 54, 70, 73, 80, 85, 86, 143, 152, 275, 278 - Rio Cuarto 7, 46, 155 Rochechouart, France 46 Roter Kamm 13 - Saltpan, South Africa 38, 46 Steen River, Canada 54, 184 - Sudbury 7, 39 - Theophilus 8 - Tswaing, South Africa 38, 46 - Tycho 59 -Vredefort 7, 10, 21, 29, 39, 52, 117, 143, 148 Wabar, Saudi Arabia 46, 47, 52, 93 -Wanapitei, Canada 54, 82, 131, 136, 268 West Clearwater, Canada 48 Zhamanshin 46, 54, 93 cratering 1, 3, 4, 5, 16, 17 diamond 24 ejecta 1, 6, 10, 14, 48, 52, 53, 139, 180, 279 excavation 19 experiments 4, 7 fallout 203,204 glass(es) 24, 36, 40, 47, 63, 69, 71, 89, 90-94, 96, 104, 111,112, 114, 120, 121, 123, 130, 131, 136, 138, 139, 142, 148 lithologies 24, 69 melt(s) 1, 7, 24, 25, 36-40, 43, 44, 4649, 51, 52, 118, 120-123, 133-137, 140, 152, 286, 293 breccia(s), 39, 40, 69 rock(s) 1, 7, 36, 37, 40, 43, 44, 46-48, 51,269, 286, 293 microspherules 206 structures 1, 6, 10-12, 21, 34, 37, 39, 40, 43, 46, 48, 49, 51-54, 57, 61, 63, 81, -
M
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n
i
r
83, 87, 88, 93, 96-99, 103, 114-117, 122-124, 131-139, 141, 143, 144, 146, 148, 151-153, 156, 168, 171, 189, 194, 268,270 winter 217 impactite(s) 29, 39, 40, 42-44, 46, 47, 48, 49,52,53,134,144,147,282,291 impactoclastic layer(s) 53, 60, 91, 101, 130, 131, 136, 143, 152, 189, 195, 258, 265-273,282,283,286 impactor(s) 15, 42, 43, 46, 60, 97, 106, 107,113,118,168,189 INAA 186,187,204,208,287,289,291 India 93, 125 Indian Ocean 82, 131,136, 152, 256 Indochina 67, 72, 74, 75, 78, 79, 80, 88, 89,130 indochinite(s) 68, 74, 78, 92, 94, 95 inoceramids 192 interplanetary dust particles 62, 189, 195, 266,268 inverted s~atigraphy 59 ion microprobe 287 Iowa 103, 115, 136-138, 194 irghizi~s 94 iridium (~) 44, 45, 48, 61, 63, 76, 91, 96, 104-107, 113, 118, 128, 129, 131, 140, 142, 143, 146-150, 154, 159, 170, 185187, 189, 195, 197, 198, 203, 204, 206, 207, 218, 220, 221,223, 239, 244, 254, 256-258, 262-266, 269,277, 287, 289, 290-292 iron - meteorite(s) 5, 15, 43, 44-46, 50, 142 - sulfide 249 isochron 52, 293 isotope - dilution 292, 293 - methods 51 isotropization 23, 29, 33 Isua (Greenland) 154 Ivory Coast, West Africa 61, 74, 79, 8688,91,92,152 strewn fields 68,75,80,86 ~kti~s 61,74,79, 86,88, 91,92
-
-
-
J/K boundary 140, 141,168, 177, 178 jadeite 34 jetting 19, 77 Jurassic- 79, 134, 139, 140-142, 151,162, 163, 168, 172, 173, 177, 179-181,219
358
- Cretaceous (J/K) boundary 140, 168 K/Tboundary 3 , 6 , 3 0 , 3 1 , 3 6 , 4 8 , 4 9 , 5 1 , 53, 61~63, 89, 101-116, 118, 120-125, 127-129, 137, 141, 143, 150, 152, 159, 164, 168, 171, 172, 190, 192, 194-204, 206-216, 218-232, 234, 236, 237, 239241, 243-249, 254, 267, 271,282-285, 289 kaolinite 102, 103, 206 K-Ar method 51, 52, 68 Kara Sea 194 Kathu core 146 Kendelbachgraben, Austria 151 kerogen 107 K-feldspar 52, 83, 133, 146, 203, 204, 206, 207, 209, 215, 220, 244, 248, 266, 267 K-feldspars 106 kimberlites 34 Kimmeridgian 163 kinetic energy 14-16 kink bands 23 kinkbanding 133 Kyoto 258 L'Annunziata section, Apiro 275 La Lajilla, Mexico 129 La Vedova section 275 Laga Formation 159, 239 Langhian 166 Langren, Michel Florent van 3 Laos 64 Late Devonian 142,148,149,150 - Eocene 82,91,101,109,130,131,136, 143, 146, 162, 165, 168, 195, 204, 207, 250, 253, 254, 256, 257, 262, 263, 265, 266,268,272,273,283,284,286 - Triassic 152, 157, 162 Triassic-Early Jurassic 157 late heavy bombardment 153, 154 layered tekfi~s 64 LDG 95-99 lech~eliefi~ 24, 34, 36, 38, 69, 74-76, 92, 93,96,111 Lias 162 Libya 95 Libyan Dese~ Glass(see LDG) 95,97-99 limestone(s) 27, 112, 129, 137, 149, 152, 159, 163-166, 172, 173, 178, 185, 195-
-
200, 203, 204, 207, 209-211,213-215, 217-219, 221-223, 228, 229, 231-233, 235-237, 239-241,244, 247, 248, 280284,286 lithic 36,39,40,57,99,227 (fragmental) breccias 39 - breccia 40 loess 64, 72, 75, 80 lonsdaleite 36 lower bathyal 210 lunar crater(s) 3-5, 7, 57, 59, 93 highlands 153 - mafia 10 Luochuan 75 Lyell, Charles 4 -
-
-
maars 3 Maastnchtian 101, 124, 128, 190, 192195,215,231,253 - crisis 190, 195 Macchia di Sole 247 Macigno 165 Madrid 107 magnesioferrite 62, 113, 114, 204, 208 - spinel 204 magnesiow~istite 113 magnetic spherules 196, 208, 266 magnetite 48, 113,208, 224, 288 Maiolica Formation 163, 178, 180, 239 majorite 34 Malaysia 91 manganese nodules 106 mantle 48, 49, 79, 107, 120, 121, 140, 153, 291,293 - rocks 48, 49, 291 Marche 53, 163 marine plankton 203, 217, 220 marly limestone(s) 164-166, 222, 251, 255, 258, 264, 269, 271,273, 275, 285, 286 Marne a Fucoidi Formation 163 a Posidonia Formation 163 del Serrone 174, 175 Marnoso-Arenacea Formation 159, 224, 227,239 Mars 5, 10, 153 Martha's Vineyard 80 maskelynite 24, 34 -
-
-
359
massextinction(s) 1, 3, 51, 53, 63, 123, 124, 127, 137, 148, 150, 151, 155, 156, 159, 168, 172, 184, 186, 189 Massa Martana 172 MASSICORE 259, 266, 268 Massignano 131, 159, 189, 195, 253, 256-259, 261,262, 264-273,283 matrix 83,208,282, 286, 291,295 Mauritania 46, 93, 94 mayaroensis limestone 241 Mediterranean 166 megabreccias 150, 163 Mekong River 80 - Valley 88 melting 19, 23, 25, 27, 34, 36, 38, 43, 64, 72, 79, 89, 92, 93, 96, 110, 133, 154, 287 Mercury 5, 10, 60 Mesozoic 133, 134, 159, 167 Messinian Gessoso-Solfifera Formation 159 salinity crisis 166 metamorphic basement 162 meteor 15 meteorite(s) 4-7, 10, 14, 15, 21, 40, 4247, 49, 50, 105, 107, 108, 139, 142, 144, 156, 291,293 meteoritic - component 38, 42--44, 46-48, 51, 91, 93, 96, 99, 107, 112, 118, 132, 139, 140, 142, 144, 279, 286 matter 198 projectile(s) 1, 10, 291 meteoroid 15 methane 130 Mexico 54, 63, 104, 105, 107, 112, 115, 116, 123, 127-130, 141 micas 23 microcline 227 micro - krystites 130, 131, 136, 146, 152, 204, 207, 214, 215, 220, 221,244, 256-258, 266, 267, 283,285 meteorites 198 - spherules 140, 206, 283 - tektites 59~1, 64, 69, 75-79, 81, 82, 85, 86, 88, 90, 91, 93, 130, 136, 146, 148, 152, 204, 207, 255-257, 269, 283, 287 Middle -
-
-
-
-
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- Eocene 165, 166, 254 /Late Miocene 168 Milankovich cyclicity 164, 185,215 Miller indices 28,297,299 mills 283, 288 Mimbral, Mexico 112, 123, 127, 128, 253 mixed layered illite-smectite 206 modification stage 14, 19 molasse 72, 86, 159, 274 Moldau 85 moldavite(s) 68, 73, 79, 84, 85 monazite 77, 96, 269 monomict - breccias 25, 40 fragmental impact breccias 39 MontagnadeiFiori 201, 203, 209, 210, 213,223,247,249 Monte - Cagnrro 256 - Cerchio 172, 173 - Cbnero 164, 166, 201, 203, 204, 209, 210, 213, 217, 222, 223, 239, 241,242, 244, 247, 256, 258 - dei Corvi 275, 277 - Nerone 163 - San Vicino 201,211,231,232 Serrone 175 Monteville Formation 146 Monti Martani 172 Sibillini 201 Moon 1, 3-5, 7-10, 14, 59, 72, 153, 156 Moravia, Czech Republic 85 mosaicism 27, 83, 118, 133, 296 Mount St. Helens 16, 108 multiple impacts 80, 103, 148, 185, 189 multiring basins 10, 117 Muong Nong-type tektites 64, 73-75, 77, 89, 90, 92, 111 -
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Namibia 13, 15 nannoplankton 103 Nebraska 137, 152 nekton 217 neritic facies 162 neutron activation analysis 154, 186, 287, 291 Nevada 149 New Zealand 5, 107, 108, 110 Ni-richspinel(s) 61, 102, 131, 258, 265, 267
360
NMR 24, 34, 154, 296 nodular chert(s) 164, 165, 178 nomenclature 39, 42, 104 Norian 168 North American - microtektite layer 78, 131 microtektites 82 - strewn field(s) 68, 73, 75, 78, 80-82, 91,130-132, 136, 256, 262 tektite(s) 74, 79, 82, 131, 133, 136, 255,269 North Atlantic 107, 130, 157, 251,256 Nova Scotia 82, 151 NTIMS 293,294 Nubian sandstone 97 nuclear explosion crater 58 magnetic resonance (see NMR) 34 -
-
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02 minimum zone 184 oblique impact(s) 7, 46, 99, 109, 117, 155 ocean floor 10 oceanic anoxic event 164, 184, 189 ODP Site - 536 105 - 588B 277 - 689B 82, 257, 277 758B 91 - 904A 82 - 1049 107, 129 olivine 17, 24, 27, 34, 288, 295 Oort cloud 156 Opik, Ernest 5 optical mosaicism 23 orbital velocity 15 orbitoids 241 ordinary chondrites 51 osmium (Os) isotope(s) 49, 93, 107, 112, 292-294 Osangularidae 209 outer rim 7, 132, 134 oxygen isotopes 79 -
P. eugubina Zone
200, 203 P0 Zone 200, 215,218 PAHs 108 Paleocene-Eocene boundary 253 Paleodychtion 211 Paleogene 159, 197, 250, 258 paleontology 6, 192 Paleozoic 132, 137, 167
palynomorphs parautochthonous rocks Paris Basin
172 39 251 Parvularuglobigerina eugubina Zone 200 PDF(s), 87, 109, 110, 118, 131, 133, 138, 139, 149, 151,208, 209, 264, 295-300 peak ring 8, 116, 118, 132 pebbly mudstones 163 pelagic 80, 182, 185, 192, 193, 195, 197, 198, 201,203, 204, 207, 210, 211,213, 215, 217, 219, 231,237, 239, 241,247, 250, 255, 258, 259, 262, 264, 269, 274 - biomicrites 237 limestones 159, t64 - ooze 203 Pefialver Formation 128 Pennide-Liguride Ocean 157 perennial fallout 198 Pering mine 146 periodicity 51, 53, 155, 156, 168 Permian134, 150, 168, 254 - Triassic boundary (P/TR) 61,150, 168, Perugia 162 Petriccio 113, 199, 203, 204, 206, 208210, 213, 214, 220, 223, 227-231,235 - outcrop 209 - section 228 petrographic microscope 283, 284, 286, 295 PFs 27-29, 32 PGE(s) 44, 47, 48, 61,102, 104-107, 113, 139, 140, 142-t44, 147, 150, 154, 282, 289, 291,292, 294 Phanerozoic 184, 254 Philippines 74 philippinite 90 photic zone 157, 217 photosynthesis 217 phytoplankton 217 Plan dell'Elmo 231 Pierre Shale, South Dakota 137, 138 piggyback basins 159 pillow basalts 207 Piobbico 181,201,256 plagioclase 24, 34, 52, 83, 133, 227, 296 planar deformation features (see PDFs), 23, 24, 27-29, 32, 34, 118, 146, 264 - features 110, 111,139, 284, 295, 300 fractures 24, 28, 154 planetesimals 153 -
-
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361
plankton 180, 190, 217, 218, 241, 254, 271,274, 275 planktonic foraminifera 165, 181, 194, 195, 197, 199, 201,209, 214, 215, 217, 218, 231,236, 237, 269, 271 Planolites 211-215, 222, 233, 234, 239, 240, 266, 267, 271 plate tectonics 4, 6, 11 platinum group elements (see PGEs) 44, 140, 142, 198,282 Pleistocene 136, 157, 159 Pliensbachian163, 168, 173, 174, 176 - Toarcian boundary (P/T) 168 Pliocene 11,166 Podrina 228 Poggio 181-183,195, 231-233, 240 Le Guaine 181,182 San Vicino 195, 231-233 polycyclic aromatic hydrocarbons (see PAHs) 108 polymict breccia(s) 25, 40, 118, 135, 136 Port Campbell, Victoria, Australia 91 power drill 281 Praeglobotruncana 184 Precambrian 79, 82, 138, 148 precision 51-53, 112, 132, 156, 167, 198, 288 pressure-solution 26, 210, 232 pseudobedding (stylolitization) 210 primary productivity 194, 195,210 productivity 211,215,217,241,254 projectile 15, 16, 19, 42, 43, 45~19, 91, 144, 209 proximal ejecta 39, 57, 59-61, 63, 104, 113, 128, t49, 282 pseudomorphic 201 pseudotachylitic breccias 25, 40 Pueblo, Colorado 185 pyrite 118, 142, 146, 203, 209, 210, 213, 220, 249 pyroxene 34 -
-
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Quagliotti quarry 244, 246 quartz 1, 17, 23, 24, 27-34, 36-38, 61, 71, 77, 78, 83, 88, 93, 96, 102, 109-111, 115, t18, 128, 131, 133, 134, t37-139, t46, 149-15t, 172, 195, 203, 204, 207209, 220, 221,227, 244, 256, 258, 262266, 269, 283-285, 287, 294-300 quartzite 32, 33, 149, 283 quenched silicate melt 204
quenching
21, 64, 72, 267
R. cushmani Racemiguemelina fructicosa
184 216
radiochemical neutron activation analysis (RNAA) 291 radiolarites 184 Raman spectroscopy 296 rare earth element(s) (REE) 37, 64, 72, 73, 94, 96, 98, 106 rare fish 209 rarefaction wave 18, 19 Raton Basin 30 Pass,Colorado 102 New Mexico t02, 107, 109 Rb-Sr 49, 51, 52, 72, 79, 80-83, 89, 112, 120, 136 - isochron method 52, 293 isotopic system 79 recrystallization 35, 37, 52, 118, 144 redox 207,210, 239 reduction 91,162, 218, 288,290, 291 REE patterns 64, 72, 73, 94, 96 refractive index 296 release wave 18, 19 relict mineral(s) 75, 77 Reophax 211 retene 108 Rhaetavicula contorta limestones 162 -
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Rhyzammina
ringwoodite RNAA Rocca Leonella Rosita contusa
Rosso Ammonitico Formation Rotalipora - cushmani
rudist(s) Rugoglobigenindae Rugoglobigerina
Russia rutile
211
24, 34 291 201 216
163, 174 184, 185 185 192, 241 197 216
12, 35, 54, 55, 115, 131,194, 277 64, 77
sample preparation 279, 282, 287, 290, 295 San Francisco 16 sandstone(s) 27, 62, 93, 96, 98, 127, 128, 132, 134, 137, 139, 224, 227, 280 sanidine 137, 206, 227, 275,284 Sassoferrato 175
362
Saudi Arabia 52 Scaglia Bianca 164, 165, 181, 182, 184, 185, 187, 188,247 - Cinerea, 164-166, 250, 255, 274 Rossa 164, 165, 181, 182, 184, 187, 188, 190, 195, 196, 198, 201,203, 209213, 215, 217-219, 222, 224, 231,237239, 241,244, 247,250, 251,253 - Variegata 164, 165,250, 255,268 scanning electron microscopy (see SEM) 287 Scheggia 175, 223 Schlier Formation 166 schlieren 64, 93, 96 Scolicia 211 secondary craters 58 sediment loading 210 seismic data 11, 117 Selli Level 163, 164, 181,182 SEM 29, 31,103, 110, 111,114, 204, 207, 208, 227, 236, 249, 267, 286-288, 295, 300 shales 27, 64, 72, 137, 138, 174 shallow water environments 184, 192 Shatsky Rise 107 shatter cones 10, 25, 26, 27, 138 shock deformation 10 - effects 29, 87, 154, 155, 282 - metamorphic 1, 3, 10, 21, 23, 24, 29, 109, 139, 154, 296 - metamorphism 10, 21-23, 27-29, 3840, 49, 77, 83, 87, 109, 118, 132, 133, 139, 143, 154, 209 - recovery experiments 22 wave(s) 1, 16-19, 22, 27, 33, 36, 42, 59 shocked minerals 3, 19, 24, 27, 33, 36, 52, 61, 75, 78, 91, 99, 103, 109, 110, 114, 130, 136, 137, 146, 148, 152, 154, 168, 170, 185, 187,279, 295 - quartz 27, 29, 35, 83, 109, 110, 133, 138, 151,220, 265, 269, 283, 284, 286, 300 Siberia 6, 12, 15, 35, 61, 82, 94, 131, 133, 135, 140, 254 siderophile element(s) 3, 43, 44, 47, 48, 60, 61, 76, 93, 96, 103, 105, 106, 130, 140, 142, 143, 146, 154, 282. 287 silica glass 29 -
siliciclastic 159, 165, 166, 198, 209, 219, 274 turbidites 165, 166 silicon carbide 36 simple craters 7, 11 Sirolo 240, 258 skeletal crystals 204, 207, 208, 267 skeletal structure 204 slope facies 164 slumping 11, 19, 129, 201,204, 231 slumps 163, 181 smectite 103,206, 286 Sm-Nd, 49, 51, 72, 79, 81-83, 89, 112, 120, 136 solar system 14, 15, 131, 156 soot 107, 108, 130 Sorosphaera 211 source crater 1, 6, 53, 57, 61, 69-71, 79, 80, 82, 83, 85, 86, 88, 89, 92-95, 99, 104, 110, 115, 132, 138, 139, 142, 148, 149 South - Africa 7, 29, 38, 46, 50-52, 55, 117, 139, 142, 143, 145-148 Australia 61,138 China Sea 80 - Dakota 137, 152 Southern Ocean 11, 82, 131,152 spallation 42 spheroids 207,224, 244, 248, 266 spherules 43, 62, 76, 81, 91, 102, 103, 106, 111, 113, 114, 130, 142-146, 148, 149, 168, 170, 172, 185, 187, 195, 196, 201, 204, 206-209, 214, 219-224, 227, 233, 234, 239, 244, 253, 256, 262, 266, 271 spindle stage 29, 284, 296 spinel 61, 62, 106, 113, 195, 204, 208, 262, 265-267, 286, 287 Spiroplectammina 210, 211,227 splash-form tektites 64, 74, 89, 90 Spoleto 172 Starkville South, Colorado 107 stepwise extinction 124 heating 53, 123 Stevns Klint 105-107, 109, 110 stishovite 24, 34, 78, 111,264 stony meteorites 15, 43 stony-iron meteorites 44 stress wave 16 -
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363
strewn field(s) 59, 64, 66, 68-75, 77, 7982, 84-86, 88, 89, 91, 93, 130-132, 136, 146, 155, 256 Subphyllochorda
211
subsidence 1,157, 159, 162, 163 rate 163 suevite 36, 37, 40, 42, 87, 134, 286 suevitic 36, 38-41 (fragmental) 25 - breccia(s) 36, 39, 40, 134 sulfur isotopes 108 Sumbar, Turkmenistan 107 superheating 36, 92, 217 supernova explosions 124 supersonic shock wave 16 -
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target 1, 7, 11, 16, 17, 19-21, 24-27, 32, 34, 35, 37, 39, 4244, 47, 49, 50, 57, 59, 60, 65, 69, 75, 77, 79, 85, 87, 91-93, 97, 98, 108, 127, 133, 139, 141, 146, 154, 155,265, 269 - rock(s) 87, 92, 98, 108, 282, 286, 293, 294 Tasman Sea 277 Tasmania 93 Teapot Dome, Wyoming 103 tectonic deformation 23, 165, 171,173 - shearing 219,224, 235 tektite(s) 52, 57, 60, 61, 63-72, 74-95, 99, 111, 112, 131, 133, 136, 152, 255-257, 262, 269 classification 69 TEM 28, 29, 36, 286, 295, 300 Tertiary 102, 107, 118, 127, 129, 140, 159, 163, 190, 192, 197, 199, 200, 203, 206, 209, 212, 214, 215, 219, 222, 223, 231, 233-237,239, 241,243-245 Terzo San Severo 172 Tethyan Ocean 157 Textulariina 209, 210, 211 Thailand 66, 68, 88 thailandites 66 thin section(s) 132, 145, 200, 204, 207, 215, 227,266, 267, 284-287, 295,298 thrust-and-fold belt 239 Tikal, Guatemala 95 tillites 155 Timor Sea 131 titano-magnetite 224 Tithonian140 -
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- Berriasian boundary 168, 177 Toarcian 168, 173, 174, 176 Tonle Sap, Cambodia 89 Torricella section (Furlo anticline) 214 Tortonian-Messinian boundary 166 trace fossils 210, 212, 213, 229, 233, 244, 271 transient cavity 19, 21, 59 transmission electron microscope (see TEM) 28, 264 Transvaal Supergroup 145, 146 Triassic159, 162, 166 - Jurassic (T~J) boundary 151, 152, 168, 172, 173 Tritaxia
211
tsunami deposits 128, 149 Tunguska, Siberia 6, 12, 15, 61, 97 turbidite 159, 164, 201, 203, 212, 222, 231,237, 244, 274 Turkmenistan 107 Turonian 164, 184, 237 Tuscan basin 165
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Ukraine 30, 54, 55 ultramafic 48, 49 Umbria-Marche 53, 101, 131, 141, 157, 161,244 Apennines 157, 161 sequence 53 uniformitarian(ism) 4, 6, 114 United States of America 12, 131, 132, 137, 185, 189 universal stage 29, 31, 118, 296, 298 U-Pb age 121 Upper Cretaceous-Oligocene 163 upper crust 65, 71, 72, 73, 91 Upper Freshwater-Molasse 86 Ural Glass 94 Uranus 3 urengoites 94 U-stage 284, 296-298, 300 U-Th-Pb dating 51, 52 Valdorb]a 173-176 vapor fractionation 75, 77, 89 vaporization 19, 36, 217 Venezuela Basin 256 Venus 5 Verneulina 211 Vietnam 88 Vispi quarry 181,182 Vltava 85
364
volatile elements 74, 89 volatilization fractionation 89 volcanic 3-7, 16, 17, 21, 35-38, 60, 167, 206, 219, 224, 253, 262, 274 - ashes 165, 166, 253 eruption(s) 6, 4, 108, 124 features 3 hypothesis 3, 4 structures 7 volcanism 1, 3, 6, 16
Wittenoom Formation Witwatersrand Basin Wolf Creek Woodside Creek, New Zealand Wyoming
146 33 46 107, 108 103
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W. archeocretacea 185 W. hornestowensis 235 Washington 258 water cooling 215 water-sediment interface 200, 203, 210, 215, 218, 219, 221,239, 248 Weddel Sea 277 Wegener, Alfred 4 Western Interior 103, 110, 185 Whiteinella archeocretacea 185 winnowing 204, 218, 239
X-ray computed tomography - diffraction - fluorescence (XRF) -
42 27, 36, 296 287
Yucatan 217 Peninsula, Mexico 63 - Mexico 115-117, 119, 120, 125
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zhamanshinites 94 zircon(s) 24, 29, 36, 52, 63, 64, 77, 78, 96, 110, 111, 121, 122, 137, 139, 140, 153, 154, 224, 269 Zoophycos 211-213, 215, 222, 223, 231, 233,239, 240, 271 zooplankton 198, 217